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Rene´ L. Schilling Renming Song Zoran Vondracˇek
Bernstein Functions Theory and Applications
De Gruyter
Authors Rene´ L. Schilling Institut für Stochastik Technische Universität Dresden 01062 Dresden, Germany
Renming Song Department of Mathematics University of Illinois Urbana, IL 61801, USA
Zoran Vondracˇek Department of Mathematics University of Zagreb 10000 Zagreb, Croatia Series Editors Carsten Carstensen Department of Mathematics Humboldt University of Berlin Unter den Linden 6 10099 Berlin, Germany E-Mail:
[email protected]
Niels Jacob Department of Mathematics Swansea University Singleton Park Swansea SA2 8PP, Wales, United Kingdom E-Mail:
[email protected]
Nicola Fusco Dipartimento di Matematica Universita` di Napoli Frederico II Via Cintia 80126 Napoli, Italy E-Mail:
[email protected]
Karl-Hermann Neeb Department of Mathematics Technische Universität Darmstadt Schloßgartenstraße 7 64289 Darmstadt, Germany E-Mail:
[email protected]
Mathematics Subject Classification 2010: 26-02, 30-02, 44-02, 31B, 46L, 47D, 60E, 60G, 60J, 62E Keywords: Bernstein function, complete Bernstein function, completely monotone function, generalized diffusion, Krein’s string theory, Laplace transform, Nevanlinna⫺Pick function, matrix monotone function, operational calculus, positive and negative definite function, potential theory, Stieltjes transform, subordination Updates and corrections can be found on www.degruyter.com/bernstein-functions
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ISBN 978-3-11-021530-4 쑔 Copyright 2010 by Walter de Gruyter GmbH & Co. KG, 10785 Berlin, Germany. All rights reserved, including those of translation into foreign languages. No part of this book may be reproduced in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the publisher. Printed in Germany. Typesetting: Da-TeX Gerd Blumenstein, Leipzig, www.da-tex.de. Printing and binding: Hubert & Co. GmbH & Co. KG, Göttingen.
Contents
Preface
vii
Index of notation
xii 1
1
Completely monotone functions
2
Stieltjes functions
11
3
Bernstein functions
15
4
Positive and negative definite functions
25
5
A probabilistic intermezzo
34
6
Complete Bernstein functions: representation
49
7
Complete Bernstein functions: properties
62
8
Thorin–Bernstein functions
73
9
A second probabilistic intermezzo
80
10 Special Bernstein functions and potentials 92 10.1 Special Bernstein functions . . . . . . . . . . . . . . . . . . . . . . 92 10.2 Hirsch’s class . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 11 The spectral theorem and operator monotonicity 110 11.1 The spectral theorem . . . . . . . . . . . . . . . . . . . . . . . . . 110 11.2 Operator monotone functions . . . . . . . . . . . . . . . . . . . . . 118 12 Subordination and Bochner’s functional calculus 130 12.1 Semigroups and subordination in the sense of Bochner . . . . . . . 130 12.2 A functional calculus for generators of semigroups . . . . . . . . . 145 12.3 Eigenvalue estimates for subordinate processes . . . . . . . . . . . 161 13 Potential theory of subordinate killed Brownian motion
174
vi
Contents
185 14 Applications to generalized diffusions 14.1 Inverse local time at zero . . . . . . . . . . . . . . . . . . . . . . . 185 14.2 First passage times . . . . . . . . . . . . . . . . . . . . . . . . . . 202 15 Examples of complete Bernstein functions 15.1 Special functions used in the tables . 15.2 Algebraic functions . . . . . . . . . 15.3 Exponential functions . . . . . . . . 15.4 Logarithmic functions . . . . . . . . 15.5 Inverse trigonometric functions . . . 15.6 Hyperbolic functions . . . . . . . . 15.7 Inverse hyperbolic functions . . . . 15.8 Gamma and other special functions . 15.9 Bessel functions . . . . . . . . . . . 15.10 Miscellaneous functions . . . . . . . 15.11 Additional comments . . . . . . . .
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214 215 218 226 228 244 244 250 254 264 272 278
A Appendix 281 A.1 Vague and weak convergence of measures . . . . . . . . . . . . . . 281 A.2 Hunt processes and Dirichlet forms . . . . . . . . . . . . . . . . . . 283 Bibliography
291
Index
309
Preface
Bernstein functions and the important subclass of complete Bernstein functions appear in various fields of mathematics—often with different definitions and under different names. Probabilists, for example, know Bernstein functions as Laplace exponents, and in harmonic analysis they are called negative definite functions. Complete Bernstein functions are used in complex analysis under the name Pick or Nevanlinna functions, while in matrix analysis and operator theory, the name operator monotone function is more common. When studying the positivity of solutions of Volterra integral equations, various types of kernels appear which are related to Bernstein functions. There exists a considerable amount of literature on each of these classes, but only a handful of texts observe the connections between them or use methods from several mathematical disciplines. This book is about these connections. Although many readers may not be familiar with the name Bernstein function, and even fewer will have heard of complete Bernstein functions, we are certain that most have come across these families in their own research. Most likely only certain aspects of these classes of functions were important for the problems at hand and they could be solved on an ad hoc basis. This explains quite a few of the rediscoveries in the field, but also that many results and examples are scattered throughout the literature; the exceedingly rich structure connecting this material got lost in the process. Our motivation for writing this book was to point out many of these connections and to present the material in a unified way. We hope that our presentation is accessible to researchers and graduate students with different backgrounds. The results as such are mostly known, but our approach and some of the proofs are new: we emphasize the structural analogies between the function classes which we believe is a very good way to approach the topic. Since it is always important to know explicit examples, we took great care to collect many of them in the tables which form the last part of the book. Completely monotone functions—these are the Laplace transforms of measures on the half-line Œ0; 1/—and Bernstein functions are intimately connected. The derivative of a Bernstein function is completely monotone; on the other hand, the primitive of a completely monotone function is a Bernstein function if it is positive. This observation leads to an integral representation for Bernstein functions: the Lévy– Khintchine formula on the half-line Z f ./ D a C b C .1 e t / .dt/; > 0: .0;1/
Although this is familiar territory to a probabilist, this way of deriving the Lévy– Khintchine formula is not the usual one in probability theory. There are many more
viii
Preface
connections between Bernstein and completely monotone functions. For example, f is a Bernstein function if, and only if, for all completely monotone functions g the composition g ı f is completely monotone. Since g is a Laplace transform, it is enough to check this for the kernel of the Laplace transform, i.e. the basic completely monotone functions g./ D e t , t > 0. A similar connection exists between the Laplace transforms of completely monotone functions, that is, double Laplace or Stieltjes transforms, and complete Bernstein functions. A function f is a complete Bernstein function if, and only if, for each t > 0 the composition .t C f .// 1 of the Stieltjes kernel .t C / 1 with f is a Stieltjes function. Note that .t C / 1 is the Laplace transform of e t and thus the functions .t C / 1 , t > 0, are the basic Stieltjes functions. With some effort one can check that complete Bernstein functions are exactly those Bernstein functions where the measure in the Lévy–Khintchine formula has a completely monotone density with respect to Lebesgue measure. From there it is possible to get a surprising geometric characterization of these functions: they are non-negative on .0; 1/, have an analytic extension to the cut complex plane C n . 1; 0 and preserve upper and lower half-planes. A familiar sight for a classical complex analyst: these are the Nevanlinna functions. One could go on with such connections, delving into continued fractions, continue into interpolation theory and from there to operator monotone functions . . . Let us become a bit more concrete and illustrate our approach with an example. The fractional powers 7! ˛ , > 0, 0 < ˛ < 1, are easily among the most prominent (complete) Bernstein functions. Recall that Z 1 ˛ f˛ ./ WD ˛ D (1) .1 e t / t ˛ 1 dt: .1 ˛/ 0 Depending on your mathematical background, there are many different ways to derive and to interpret (1), but we will follow probabilists’ custom and call (1) the Lévy– Khintchine representation of the Bernstein function f˛ . At this point we do not want to go into details, instead we insist that one should read this formula as an integral representation of f˛ with the kernel .1 e t / and the measure c˛ t ˛ 1 dt . This brings us to negative powers, and there is another classical representation Z 1 1 ˇ D e t t ˇ 1 dt; ˇ > 0; (2) .ˇ/ 0 showing that 7! ˇ is a completely monotone function. It is no accident that the reciprocal of the Bernstein function ˛ , 0 < ˛ < 1, is completely monotone, nor is it an accident that the representing measure c˛ t ˛ 1 dt of ˛ has a completely monotone density. Inserting the representation (2) for t ˛ 1 into (1) and working out the double integral and the constant, leads to the second important formula for the fractional powers, Z 1 1 ˛ D (3) t ˛ 1 dt: .˛/.1 ˛/ 0 C t
Preface
ix
We will call this representation of ˛ the Stieltjes representation. To explain why this is indeed an appropriate name, let us go back to (2) and observe that t ˛ 1 is a Laplace transform. This shows that ˛ , ˛ > 0, is a double Laplace or Stieltjes transform. Another non-random coincidence is that Z 1 f˛ ./ 1 1 D t ˛ 1 dt .˛/.1 ˛/ 0 C t is a Stieltjes transform and so is ˛ D 1=f˛ ./. This we can see if we replace t ˛ 1 by its integral representation (2) and use Fubini’s theorem: Z 1 1 1 1 (4) D ˛D t ˛ dt: f˛ ./ .˛/.1 ˛/ 0 C t It is also easy to see that the fractional powers 7! ˛ D exp.˛ log / extend analytically to the cut complex plane C n . 1; 0. Moreover, z ˛ maps the upper half-plane into itself; actually it contracts all arguments by the factor ˛. Apart from some technical complications this allows to surround the singularities of f˛ —which are all in . 1; 0/—by an integration contour and to use Cauchy’s theorem for the half-plane to bring us back to the representation (3). Coming back to the fractional powers ˛ , 0 < ˛ < 1, we derive yet another R representation formula. First note that ˛ D 0 ˛s .1 ˛/ ds and that the integrand s .1 ˛/ is a Stieltjes function which can be expressed as in (4). Fubini’s theorem and the elementary equality
Z 0
1 ds D log 1 C t Cs t
yield ˛ D .˛/.1
1
Z
˛
˛/
0
log 1 C t
t˛
1
dt:
(5)
This representation will be called the Thorin representation of ˛ . Not every complete Bernstein function has a Thorin representation. The critical step in deriving (5) was the fact that the derivative of ˛ is a Stieltjes function. What has been explained for fractional powers can be extended in various directions. On the level of functions, the structure of (1) is characteristic for the class BF of Bernstein functions, (3) for the class CBF of complete Bernstein functions, and (5) for the Thorin–Bernstein functions TBF. If we consider exp. tf / with f from BF, CBF or TBF, we are led to the corresponding families of completely monotone functions and measures. Apart from some minor conditions, these are the infinitely divisible distributions ID, the Bondesson class of measures BO and the generalized Gamma convolutions GGC. The diagrams in Remark 9.17 illustrate these connections. If we
x
Preface
replace (formally) by A, where A is a negative semi-definite matrix or a dissipative closed operator, then we get from (1) and (2) the classical formulae for fractional powers, while (3) turns into Balakrishnan’s formula. Considering BF and CBF we obtain a fully-fledged functional calculus for generators and potential operators. Since complete Bernstein functions are operator monotone functions we can even recover the famous Heinz–Kato inequality. Let us briefly describe the content and the structure of the book. It consists of three parts. The first part, Chapters 1–10, introduces the basic classes of functions: the positive definite functions comprising the completely monotone, Stieltjes and Hirsch functions, and the negative definite functions which consist of the Bernstein functions and their subfamilies—special, complete and Thorin–Bernstein functions. Two probabilistic intermezzi explore the connection between Bernstein functions and certain classes of probability measures. Roughly speaking, for every Bernstein function f the functions exp. tf /, t > 0, are completely monotone, which implies that exp. tf / is the Laplace transform of an infinitely divisible sub-probability measure. This part of the book is essentially self-contained and should be accessible to non-specialists and graduate students. In the second part of the book, Chapter 11 through Chapter 14, we turn to applications of Bernstein and complete Bernstein functions. The choice of topics reflects our own interests and is by no means complete. Notable omissions are applications in integral equations and continued fractions. Among the topics are the spectral theorem for self-adjoint operators in a Hilbert space and a characterization of all functions which preserve the order (in quadratic form sense) of dissipative operators. Bochner’s subordination plays a fundamental role in Chapter 12 where also a functional calculus for subordinate generators is developed. This calculus generalizes many formulae for fractional powers of closed operators. As another application of Bernstein and complete Bernstein functions we establish estimates for the eigenvalues of subordinate Markov processes. This is continued in Chapter 13 which contains a detailed study of excessive functions of killed and subordinate killed Brownian motion. Finally, Chapter 14 is devoted to two results in the theory of generalized diffusions, both related to complete Bernstein functions through Kre˘ın’s theory of strings. Many of these results appear for the first time in a monograph. The third part of the book is formed by extensive tables of complete Bernstein functions. The main criteria for inclusion in the tables were the availability of explicit representations and the appearance in mathematical literature. In the appendix we collect, for the readers’ convenience, some supplementary results. We started working on this monograph in summer 2006, during a one-month workshop organized by one of us at the University of Marburg. Over the years we were supported by our universities: Institut für Stochastik, Technische Universität Dresden,
Preface
xi
Department of Mathematics, University of Illinois, and Department of Mathematics, University of Zagreb. We thank our colleagues for a stimulating working environment and for many helpful discussions. Considerable progress was made during the two week Research in Pairs programme at the Mathematisches Forschungsinstitut in Oberwolfach where we could enjoy the research atmosphere and the wonderful library. Our sincere thanks go to the institute and its always helpful staff. Panki Kim and Hrvoje Šiki´c read substantial parts of the manuscript. We are grateful for their comments which helped to improve the text. We thank the series editor Niels Jacob for his interest and constant encouragement. It is a pleasure to acknowledge the support of our publisher, Walter de Gruyter, and its editors Robert Plato and Simon Albroscheit. Writing this book would have been impossible without the support of our families. So thank you, Herta, Jean and Sonja, for your patience and understanding. Dresden, Urbana and Zagreb October 2009
René Schilling Renming Song Zoran Vondraˇcek
Index of notation
This index is intended to aid cross-referencing, so notation that is specific to a single section is generally not listed. Some symbols are used locally, without ambiguity, in senses other than those given below; numbers following an entry are page numbers. Unless otherwise stated, binary operations between functions such as f ˙ g, f g, j !1
f ^ g, f _ g, comparisons f 6 g, f < g or limiting relations fj ! f , limj fj , lim infj fj , lim supj fj , supj fj or infj fj are always understood pointwise.
Operations and operators a_b a^b L
maximum of a and b minimum of a and b Laplace transform, 1
P S SBF TBF
potentials, 45 Stieltjes functions, 11 special Bernstein fns, 92 Thorin–Bernstein fns, 73
Sub- and superscripts Sets C "
H H# ! H N positive negative
¹z 2 C W Im z > 0º ¹z 2 C W Im z < 0º ¹z 2 C W Re z > 0º natural numbers: 1; 2; 3; : : : always in the sense > 0 always in the sense < 0
Spaces of functions B C H S BF CBF CM H
Borel measurable functions continuous functions harmonic functions, 179 excessive functions, 178 Bernstein functions, 15 complete Bernstein fns, 49 completely monotone fns, 2 Hirsch functions, 105
? b c f
sets: non-negative elements, functions: non-negative part non-trivial elements (6 0) orthogonal complement bounded compact support subordinate w.r.t. the Bernstein function f
Spaces of distributions BO CE Exp GGC ID ME SD
Bondesson class, 80 convolutions of Exp, 87 exponential distributions, 88 generalized Gamma convolutions, 84 infinitely divisible distr., 37 mixtures of Exp, 81 self-decomposable distr., 41
Chapter 1
Laplace transforms and completely monotone functions
In this chapter we collect some preliminary material which we need later on in order to study Bernstein functions. As usual, we define the (one-sided) Laplace transform of a function m W Œ0; 1/ ! Œ0; 1/ or a measure on the half-line Œ0; 1/ by L .mI / WD
1
Z
e
t
or L .I / WD
m.t/ dt
0
Z e
t
.dt/;
(1.1)
Œ0;1/
respectively, whenever these integrals converge. Obviously, L m D L m if m .dt/ denotes the measure m.t/ dt. The following real-analysis lemma is helpful in order to show that finite measures are uniquely determined in terms of their Laplace transforms. Lemma 1.1. We have for all t; x > 0 lim e
!1
t
X .t/k D 1Œ0;x .t/: kŠ
(1.2)
k6x
Proof. Let us rewrite (1.2) in probabilistic terms: if X is a Poisson random variable with parameter t, (1.2) states that lim P.X 6 x/ D 1Œ0;x .t/:
!1
From the basic formulae for the mean value and the variance of Poisson random variables, EX D t and VarX D E..X t/2 / D t, we find for t > x with Chebyshev’s inequality P.X 6 x/ 6 P jX
tj > .t
x/
E..X t/2 / 2 .t x/2 t !1 D 2 ! 0: 2 .t x/ 6
2
1 Completely monotone functions
If t 6 x, a similar calculation yields P.X 6 x/ D 1
P X
t > .x
>1
P jX
tj > .x
t/ t/
!1
!1
0;
and the claim follows. Proposition 1.2. A measure supported in Œ0; 1/ is finite if, and only if, L .I 0C/ < 1. The measure is uniquely determined by its Laplace transform. Proof. The first part from monotone convergence since we R of the assertion follows R have Œ0; 1/ D Œ0;1/ 1 d D lim!0 Œ0;1/ e t .dt/. For the uniqueness part we use first the differentiation lemma for parameter dependent integrals to get Z k .k/ . 1/ L .I / D e t t k .dt/: Œ0;1/
Therefore, X
. 1/k L .k/ .I /
k6x
X Z k .t/k D e kŠ Œ0;1/ kŠ
t
.dt/
X .t/k e kŠ
t
.dt/
k6x
Z D
Œ0;1/
k6x
and we conclude with Lemma 1.1 and dominated convergence that lim
!1
X k6x
k
. 1/ L
.k/
k .I / D kŠ
Z Œ0;1/
1Œ0;x .t/ .dt/ D Œ0; x:
(1.3)
This shows that can be recovered from (all derivatives of) its Laplace transform. It is possible to characterize the range of Laplace transforms. For this we need the notion of complete monotonicity. Definition 1.3. A function f W .0; 1/ ! R is a completely monotone function if f is of class C 1 and . 1/n f .n/ ./ > 0
for all n 2 N [ ¹0º and > 0:
(1.4)
The family of all completely monotone functions will be denoted by CM. The conditions (1.4) are often referred to as Bernstein–Hausdorff–Widder conditions. The next theorem is known as Bernstein’s theorem.
3
1 Completely monotone functions
The version given below appeared for the first time in [34] and independently in [287]. Subsequent proofs were given in [98] and [86]. The theorem may be also considered as an example of the general integral representation of points in a convex cone by means of its extremal elements. See Theorem 4.8 and [69] for an elementary exposition. The following short and elegant proof is taken from [212]. Theorem 1.4 (Bernstein). Let f W .0; 1/ ! R be a completely monotone function. Then it is the Laplace transform of a unique measure on Œ0; 1/, i.e. for all > 0, Z f ./ D L .I / D e t .dt/: Œ0;1/
Conversely, whenever L .I / < 1 for every > 0, 7! L .I / is a completely monotone function. Proof. Assume first that f .0C/ D 1 and f .C1/ D 0. Let > 0. For any a > 0 and any n 2 N, we see by Taylor’s formula n 1 X f .k/ .a/ f ./ D . kŠ
Z
k
a/ C
kD0
n 1 X . 1/k f .k/ .a/ D .a kŠ
a k
f .n/ .s/ . .n 1/Š
/ C
kD0
a
Z
s/n
1
ds
. 1/n f .n/ .s/ .s .n 1/Š
/n
1
ds:
(1.5)
If a > , then by the assumption all terms are non-negative. Let a ! 1. Then Z lim
a
a!1
. 1/n f .n/ .s/ .s .n 1/Š
/n
1
Z ds D
1
. 1/n f .n/ .s/ .s .n 1/Š
/n
1
ds
6 f ./: This implies that the sum in (1.5) converges for every n 2 N as a ! 1. Thus, every term converges as a ! 1 to a non-negative limit. For n > 0 let . 1/n f .n/ .a/ .a a!1 nŠ
n ./ D lim
/n :
This limit does not depend on > 0. Indeed, for > 0, . 1/n f .n/ .a/ .a a!1 nŠ . 1/n f .n/ .a/ D lim .a a!1 nŠ
n ./ D lim
/n /n
.a .a
/n D n ./: /n
4
1 Completely monotone functions
Let cn D
Pn
1 kD0 k ./.
Then Z
f ./ D cn C
1
. 1/n f .n/ .s/ .s .n 1/Š
/n
1
ds:
Clearly, f ./ > cn for all > 0. Let ! 1. Since f .C1/ D 0, it follows that cn D 0 for every n 2 N. Thus we have obtained the following integral representation of the function f : Z 1 . 1/n f .n/ .s/ .s /n 1 ds: f ./ D (1.6) .n 1/Š By the monotone convergence theorem Z 1 . 1/n f .n/ .s/ n 1 D lim f ./ D s .n 1/Š !0 0
1
ds:
(1.7)
Let fn .s/ D
. 1/n .n/ n n nC1 f : nŠ s s
(1.8)
Using (1.7) and changing variables according to s=t, it follows that for every n 2 N, fn is a probability density function on .0; 1/. Moreover, the representation (1.6) can be rewritten as Z 1 n 1 . 1/n f .n/ .s/ n 1 f ./ D 1 s ds s C .n 1/Š 0 Z 1 t n 1 (1.9) D 1 fn .t / dt: n C 0 By Helly’s selection theorem, Corollary A.8, there exist a subsequence .nk /k>1 and a probability measure on .0; 1/ such that fnk .t/ dt converges weakly to .dt/. Further, for every > 0, t n 1 D e t lim 1 n!1 n C uniformly in t 2 .0; 1/. By taking the limit in (1.9) along the subsequence .nk /k>1 , it follows that Z f ./ D e t .dt/: .0;1/
Uniqueness of follows from Proposition 1.2. Assume now that f .0C/ < 1 and f .C1/ D 0. By looking at f =f .0C/ we see that the representing measure for f is uniquely given by f .0C/.
1 Completely monotone functions
5
Now let f be an arbitrary completely monotone function with f .C1/ D 0. For every a > 0, define fa ./ WD f . C a/, > 0. Then fa is a completely monotone function with fa .0C/ D f .a/ < 1 and fa .C1/ D 0. By what has been already R proved, there exists a unique finite measure a on .0; 1/ such that fa ./ D .0;1/ e t a .dt/. It follows easily that for b > 0 we have e at a .dt/ D e bt b .dt/. This shows that we can consistently define the measure on .0; 1/ by .dt/ D e at a .dt/, a > 0. In particular, the representing measure is uniquely determined by f . Now, for > 0, Z f ./ D f=2 .=2/ D e . =2/t =2 .dt/ .0;1/
Z D
e
t .=2/t
e
.0;1/
Z =2 .dt/ D
e
t
.dt/:
.0;1/
Finally, if f .C1/ D c > 0, add cı0 to . For the converse we set f ./ WD L .I /. Fix > 0 and pick 2 .0; /. Since t n D n .t/n 6 nŠ n e t for all t > 0, we find Z Z nŠ nŠ t n e t .dt/ 6 n e . /t .dt/ D n L .I / Œ0;1/ Œ0;1/ and this shows that we may use the differentiation lemma for parameter dependent integrals to get Z Z dn t . 1/n f .n/ ./ D . 1/n e .dt/ D t n e t .dt/ > 0: n d Œ0;1/ Œ0;1/ Remark 1.5. The last formula in the proof of Theorem 1.4 shows, in particular, that f .n/ ./ ¤ 0 for all n > 1 and all > 0 unless f 2 CM is identically constant. Corollary 1.6. The set CM of completely monotone functions is a convex cone, i.e. sf1 C tf2 2 CM
for all s; t > 0 and f1 ; f2 2 CM;
which is closed under multiplication, i.e. 7! f1 ./f2 ./ is in CM for all f1 ; f2 2 CM; and under pointwise convergence: ¯ ® CM D L W is a finite measure on Œ0; 1/ (the closure is taken with respect to pointwise convergence).
6
1 Completely monotone functions
Proof. That CM is a convex cone follows immediately from the definition of a completely monotone function or, alternatively, from the representation formula in Theorem 1.4. If j denotes the representing measure of fj , j D 1; 2, the convolution “ Œ0; u WD 1 ? 2 Œ0; u WD 1Œ0;u .s C t/ 1 .ds/2 .dt/ Œ0;1/Œ0;1/
is the representing measure of the product f1 f2 . Indeed, Z Z Z e u .du/ D e .sCt/ 1 .ds/2 .dt/ D f1 ./f2 ./: Œ0;1/
Œ0;1/
Œ0;1/
Write M WD ¹L W is a finite measure on Œ0; 1/º. Theorem 1.4 shows that M CM M . We are done if we can show that CM is closed under pointwise convergence. For this choose a sequence .fn /n2N CM such that limn!1 fn ./ D f ./ exists for every > 0. If n denotes the representing measure of fn , we find for every a > 0 Z n!1 a n Œ0; a 6 e e t n .dt/ 6 e a fn ./ ! e a f ./ Œ0;a
which means that the family of measures .n /n2N is bounded in the vague topology, hence vaguely sequentially compact, see Appendix A.1. Thus, there exist a subsequence .nk /k2N and some measure such that nk ! vaguely. For 2 Cc Œ0; 1/ with 0 6 6 1, we find Z Z t .t/e .dt/ D lim .t/e t nk .dt/ 6 lim inf fnk ./ D f ./: k!1 Œ0;1/
Œ0;1/
k!1
Taking the supremum over all such , we can use monotone convergence to get Z e s .dt/ 6 f ./: Œ0;1/
On the other hand, we find for each a > 0 Z Z t fnk ./ D e nk .dt/ C Œ0;a/
Z e
6 Œ0;a/
t
nk .dt/ C e
e
1 2 t
e
1 2 t
Œa;1/ 1 2 a
f nk
nk .dt/
1 : 2
If we let k ! R 1 and then a ! 1 along a sequence of continuity points of we get f ./ 6 Œ0;1/ e t .dt/ which shows that f 2 CM and that the measure is actually independent of the particular subsequence. In particular, D limn!1 n vaguely in the space of measures supported in Œ0; 1/.
1 Completely monotone functions
7
The seemingly innocuous closure assertion of Corollary 1.6 actually says that on the set CM the notions of pointwise convergence, locally uniform convergence, and even convergence in the space C 1 .0; 1/ coincide. This situation reminds remotely of the famous Montel’s theorem from the theory of analytic functions, see e.g. Berenstein and Gay [21, Theorem 2.2.8]. Corollary 1.7. Let .fn /n2N be a sequence of completely monotone functions such that the limit limn!1 fn ./ D f ./ exists for all 2 .0; 1/. Then f 2 CM and .k/ limn!1 fn ./ D f .k/ ./ for all k 2 N [ ¹0º locally uniformly in 2 .0; 1/. Proof. From Corollary 1.6 we know already that f 2 CM. Moreover, we have seen that the representing measures n of fn converge vaguely in Œ0; 1/ to the representing measure of f . By the differentiation lemma for parameter dependent integrals we infer Z .k/ k fn ./ D . 1/ t k e t n .dt/ Œ0;1/
n!1
! . 1/
k
Z
tk e
t
Œ0;1/
.dt/ D f .k/ ./;
since t 7! t k e t is a function that vanishes at infinity, cf. (A.3) in Appendix A.1. Finally, assume that j j 6 ı for some ı > 0. Using the elementary estimate je t e t j 6 j j t e .^/t , ; ; t > 0, we conclude that for ; > and all >0 Z ˇ .k/ ˇ ˇ t ˇ ˇf ./ f .k/ ./ˇ 6 ˇe e t ˇ t k n .dt/ n n .0;1/
Z 6ı
e
.^/t kC1
t
n .dt/
.0;1/
ˇ ˇ D ı ˇfn.kC1/ . ^ /ˇ: .kC1/
Using that limn!1 fn . ^ / D f .kC1/ . ^ /, we find for sufficiently large values of n ˇ ˇ .k/ ˇ ˇ ˇf ./ f .k/ ./ˇ 6 2ı sup ˇf .kC1/ . /ˇ: n n
>
.k/
This proves that the functions fn are uniformly equicontinuous on Œ; 1/. There.k/ fore, the convergence limn!1 fn ./ D f .k/ ./ is locally uniform on Œ; 1/ for every > 0. Since > 0 was arbitrary, we are done. Remark 1.8. The representation formula for completely monotone functions given in Theorem 1.4 has an interesting interpretation in connection with the Kre˘ın–Milman theorem and the Choquet representation theorem. The set ® ¯ f 2 CM W f .0C/ D 1
8
1 Completely monotone functions
is a basis of the convex cone CMb , and its extremal points are given by e t ./ D e
t
;
0 6 t < 1;
e1 ./ D 1¹0º ./;
and
see Phelps [234, Lemma 2.2], Lax [199, p. 139] or the proof of Theorem 4.8. These extremal points are formally defined for 2 Œ0; 1/ with the understanding that e1 j.0;1/ 0. Therefore, the representation formula from Theorem 1.4 becomes a Choquet representation of the elements of CMb , Z Z e t .dt/ D e t .dt/; 2 .0; 1/: Œ0;1/
Œ0;1
In particular, the functions e t j.0;1/ are prime examples of completely monotone functions. Theorem 1.4 and Corollary 1.6 tell us that every f 2 CM can be written as an ‘integral mixture’ of the extremal CM-functions ¹e t j.0;1/ W 0 6 t < 1º. It was pointed out in [256] that the conditions (1.4) are redundant. The following proof of this fact is from [109]. Proposition 1.9. Let f W .0; 1/ ! R be a C 1 function such that f > 0, f 0 6 0 and . 1/n f .n/ > 0 for infinitely many n 2 N. Then f is a completely monotone function. Proof. Let n > 2 be such that . 1/n f .n/ ./ > 0 for all > 0. By Taylor’s formula, for every a > 0 n 1 X f .k/ .a/ f ./ D . kŠ
k
a/ C . 1/
kD0
If n is even f ./ >
n
Z a
. 1/n f .n/ .s/ . .n 1/Š
n 1 X f .k/ .a/ . kŠ
a/k ;
n 1 X f .k/ .a/ . kŠ
a/k :
s/n
1
ds:
kD0
while for n odd f ./ 6
kD0
a/n 1 ,
Dividing by . letting ! 1, and by using that f ./ is non-increasing, we arrive at f .n 1/ .a/ 6 0 in case n is even, and f .n 1/ .a/ > 0 in case n is odd. Thus, . 1/n 1 f .n 1/ .a/ > 0. It follows inductively that . 1/k f .k/ .a/ > 0 for all k D 0; 1; : : : ; n. Since n can be taken arbitrarily large, and a > 0 is arbitrary, the proof is completed.
1 Completely monotone functions
9
Comments 1.10. Standard references for Laplace transforms include D. V. Widder’s monographs [289, 290] and Doetsch’s treatise [80]. For a modern point of view we refer to Berg and Forst [29] and Berg, Christensen and Ressel [28]. The most comprehensive tables of Laplace transforms are the Bateman manuscript project [91] and the tables by Prudnikov, Brychkov and Marichev [239]. The concept of complete monotonicity seems to go back to S. Bernstein [32] who studied functions on an interval I R having positive derivatives of all orders. If I D . 1; 0 this is, up to a change of sign in the variable, complete monotonicity. In later papers, Bernstein refers to functions enjoying this property as absolument monotone, see the appendix première note, [33, pt. IV, p. 190], and in [34] he states and proves Theorem 1.4 for functions on the negative half-axis. Following Schur (probably [258]), Hausdorff [123, p. 80] calls a sequence .n /n2N total monoton— the literal translation totally monotone is only rarely used, e.g. in Hardy [118]; the modern terminology is completely monotone and appears for the first time in [287]—if all iterated differences . 1/k k n are non-negative where nR WD nC1 n . Hausdorff focusses in [123, 124] on the moment problem: the n are of the form .0;1 t n .dt / for some measure on .0; 1 if, and only if, the sequence R .n /n2N[¹0º is total monoton; moreover, he introduces the moment function WD .0;1 t .dt / which he also e u ; u 2 Œ0; 1/, shows R calls total monoton. A simple change of variables .0; 1 3 t that D Œ0;1/ e u .du/ Q for some suitable image measure Q of . This means that every moment sequence gives rise to a unique completely monotone function. The converse is much easier since Z e
u
Œ0;1/
.du/ Q D
Z 1 X . 1/n n un .du/: Q nŠ Œ0;1/
nD0
Many historical comments can be found in the second part, pp. 29–44, of Ky Fan’s memoir [94]. For an up-to-date survey we recommend the scholarly commentary by Chatterji [63] written for Hausdorff’s collected works [125]. More general higher monotonicity properties of the type that f satisfies (1.4) only for n 2 ¹0; 1; : : : ; N º, N 2 N [ ¹0º, were used by Hartman [119] in connection with Bessel functions and solutions of second-order ordinary differential equations. Further applications of CM and related functions to ordinary differential equations can be found, e.g. in Lorch et al. [204] and Mahajan and Ross [207], see also the study by van Haeringen [282] and the references given there. The connection between integral equations and CM are extensively covered in the monographs by Gripenberg et al. [112] and Prüss [240]. A by-product of the proof of Proposition 1.2 is an example of a so-called real inversion formula for Laplace transforms. Formula (1.3) is due to Dubourdieu [86] and Feller [98], see also Pollard [238] and Widder [289, p. 295] and [290, Chapter 6]. Our presentation follows Feller [100, VII.6]. The proof of Bernstein’s theorem, Theorem 1.4, also contains a real inversion formula for the Laplace transform: (1.8) coincides with the operator Lk;y .f .// of Widder [290, p. 140] and, up to a constant, also [289, p. 288]. Since the proof of Theorem 1.4 relies on a compactness argument using subsequences, the weak limit fnk .t / dt ! .dt / might depend on the actual subsequence .nk /k2N . If we combine this argument with Proposition 1.2, we get at once that all subsequences lead to the same and that, therefore, the weak limit of the full sequence fn .t / dt ! .dt / exists. The representation (1.6) R 1was also obtained in [87] in the following way: because of f .C1/ D 0 we can write f ./ D . 1/f 0 .t1 / dt1 . Since f 0 isR again completely monotone and satisfies 1R1 f 0 .C1/ D 0, the same argument proves that f ./ D t1 f 00 .t2 / dt2 dt1 . By induction, for every n 2 N, Z Z Z 1
f ./ D
1
t1
1
tn
. 1/n f .n/ .tn / dtn dt2 dt1 :
1
The representation (1.6) follows by using Fubini’s theorem and reversing the order of integration. The rest of the proof is now similar to our presentation. It is possible to avoid the compactness argument in Theorem 1.4 and to give an ‘intuitionistic’ proof, see van Herk [284, Theorem 33] who did this for the class S (denoted by ¹F º in [284]) of Stieltjes functions which is contained in CM; his arguments work also for CM.
10
1 Completely monotone functions
A proof of Theorem 1.4 using Choquet’s theorem or the Kre˘ın–Milman theorem can be found in Kendall [170], Meyer [214] or Choquet [69, 68]. A modern textbook version is contained in Lax [199, Chapter 14.3, p. 138], Phelps [234, Chapter 2], Becker [19] and also in Theorem 4.8 below. Gneiting’s short note [109] contains an example showing that one cannot weaken the Bernstein–Hausdorff–Widder conditions beyond what is stated in Proposition 1.9. There is a deep geometric connection between completely monotone functions and the problem when a metric space can be embedded into a Hilbert space H. The basic result is due to Schoenberg [255] who proves that a function f on Œ0; 1/ with f .0/ D f .0C/ is completely monotone if, and only if, 7! f .jj2 /, 2 Rd , is positive definite for all dimensions d > 0, cf. Theorem 12.14.
Chapter 2
Stieltjes functions
Stieltjes functions are a subclass of completely monotone functions. They will play a central role in our study of complete Bernstein functions. In Theorem 7.3 we will see that f is a Stieltjes function if, and only if, 1=f is a complete Bernstein function. This allows us to study Stieltjes functions via the set of all complete Bernstein functions which is the focus of this tract. Therefore we restrict ourselves to the definition and a few fundamental properties of Stieltjes functions. Definition 2.1. A (non-negative) Stieltjes function is a function f W .0; 1/ ! Œ0; 1/ which can be written in the form Z a 1 f ./ D C b C (2.1) .dt/ .0;1/ C t where a; b > 0 are non-negative constants and is a measure on .0; 1/ such that R .1 C t/ 1 .dt/ < 1. We denote the family of all Stieltjes functions by S. .0;1/ The integral appearing in (2.1) is also called the Stieltjes transform of the meaR1 sure . Using the elementary relation . C t/ 1 D 0 e tu e u du and Fubini’s theorem one sees that it is also a double Laplace transform. In view of the uniqueness of the Laplace transform, see Proposition 1.2, a; b and appearing in the representation (2.1) are uniquely determined by f . Since some authors consider measures on the compactification Œ0; 1, there is no marked difference between Stieltjes transforms and Stieltjes functions in the sense of Definition 2.1. It is sometimes useful to rewrite (2.1) in the following form Z 1Ct f ./ D (2.2) .dt/ N Ct Œ0;1 where N WD aı0 C .1 C t/ 1 .dt/ C bı1 is a finite measure on the compact interval Œ0; 1. Since for z D C i 2 C n . 1; 0 and t > 0 ˇ ˇ ˇ 1 ˇ 1 1 ˇ ˇ ; ˇz C t ˇ D p 2 2 t C1 . C t/ C i.e. there exist two positive constants c1 < c2 (depending on and ) such that c1 c2 1 6 6p ; 2 2 t C1 t C1 . C t/ C
12
2 Stieltjes functions
we can use (2.2) to extend f 2 S uniquely to an analytic function on C n . 1; 0. Note that 1 .Im z/2 Im z Im z Im D Im z D zCt jz C tj2 jz C tj2 which means that the mapping z 7! f .z/ swaps the upper and lower complex halfplanes. We will see in Corollary 7.4 below that this property is also sufficient to characterize f 2 S. Theorem 2.2.
(i) Every f 2 S is of the form
f ./ D L .a dt I / C L b ı0 .dt/I C L L .I t/ dtI for the measure appearing in (2.1). In particular, S CM and S consists of all completely monotone functions having a representation measure with completely monotone density on .0; 1/. (ii) The set S is a convex cone: if f1 ; f2 2 S, then sf1 C tf2 2 S for all s; t > 0. (iii) The set S is closed under pointwise limits: if .fn /n2N S and if the limit limn!1 fn ./ D f ./ exists for all > 0, then f 2 S. R1 Proof. Since . C t/ 1 D 0 e .Ct/u du, assertion (i) follows from (2.1) and Fubini’s theorem; (ii) is obvious. For (iii) we argue as in the proof of Corollary 1.6: assume that fn is given by (2.2) where we denote the representing measure by N n D an ı0 C .1 C t/ 1 n .dt/ C bn ı1 . Since N n Œ0; 1 D fn .1/
n!1
! f .1/ < 1;
the family .N n /n2N is uniformly bounded. By the Banach–Alaoglu theorem, Corollary A.6, we conclude that .N n /n2N has a weak* convergent subsequence .N nk /k2N such that N WD vague- limk!1 N nk is a bounded measure on the compact space Œ0; 1. Since t 7! .1 C t/=. C t/ is in C Œ0; 1, we get Z Z 1Ct 1Ct N nk .dt/ D .dt/; N f ./ D lim fnk ./ D lim k!1 k!1 Œ0;1 C t Œ0;1 C t i.e. f 2 S. Since the limit limn!1 fn ./ D f ./ exists—independently of any subsequence—and since the representing measure is uniquely determined by the function f , N does not depend on any subsequence. In particular, D limn!1 n vaguely in the space of measures supported in .0; 1/. Remark 2.3. Let f; fn 2 S, n 2 N, where we write a; b; and an ; bn ; n for the constants and measures appearing in (2.1) and N n ; N for the corresponding representation measures from (2.2). If limn!1 fn ./ D f ./, the proof of Theorem 2.2 shows that vague- lim n D n!1
and
vague- lim N n D : N n!1
2 Stieltjes functions
13
Combining this with the portmanteau theorem, Theorem A.7, it is possible to show that Z n .dt/ a D lim lim inf an C !0 n!1 .0;/ 1 C t and
Z
b D lim lim inf bn C R!1 n!1
.R;1/
n .dt/ I 1Ct
in the above formulae we can replace lim infn by lim supn . We do not give the proof here, but we refer to a similar situation for Bernstein functions which is worked out in Corollary 3.8. In general, it is not true that limn!1 an D a or limn!1 bn D b. This is easily seen from the following examples: fn ./ D 1C1=n and fn ./ D 1=n . Remark 2.4. Just as in the case of completely monotone functions, see Remark 1.8, we can understand the representation formula (2.2) as a particular case of the Kre˘ın– Milman or Choquet representation. The set ® ¯ f 2 S W f .1/ D 1 is a basis of the convex cone S, and its extremal points are given by e0 ./ D
1 ;
e t ./ D
1Ct ; 0 < t < 1; Ct
and
e1 ./ D 1:
To see that the functions e t , 0 6 t 6 1, are indeed extremal, note that the equality e t ./ D f ./ C .1
/g./;
f; g 2 S;
and the uniqueness of the representing measures in (2.2) imply that ı t D Nf C .1
/N g
(Nf ; N g are the representing measures) which is only possible if Nf D N g D ı t . Conversely, since every f 2 S is given by (2.2), the family ¹e t º t 2Œ0;1 contains all extremal points. In particular, 1;
1 ;
1 ; Ct
1Ct ; Ct
t > 0;
are examples of Stieltjes functions and so are their integral mixtures, e.g. ˛
1
.0 < ˛ < 1/;
1 1 p arctan p ;
1 log.1 C /
14
2 Stieltjes functions
p or 1 1.1;1/ .t / dt as which we obtain if we choose 1 sin.˛/ t ˛ 1 dt , 1.0;1/ .t/ dt t 2 t the representing measures .dt/ in (2.1). The closure assertion of Theorem 2.2 says, in particular, that on the set S the notions of pointwise convergence, locally uniform convergence, and even convergence in the space C 1 coincide, cf. also Corollary 1.7.
Comments 2.5. The Stieltjes transform appears for the first time in the famous papers [268, 269] where T. J. Stieltjes investigates continued fractions in order to solve what we nowadays call the Stieltjes Moment Problem. For an appreciation of Stieltjes’ achievements see the contributions of W. van Assche and W. A. J. Luxemburg in [270, Vol. 1]. The name Stieltjes transform for the integral (2.1) R was coined by Doetsch [79] and, independently, Widder [288]. Earlier works, e.g. Perron [231], call . C t / 1 .dt / Stieltjes integral (German: Stieltjes’sches Integral) but terminology has changed since then. Sometimes the name Hilbert–Hankel transform is also used in the literature, cf. Lax [199, p. 185]. A systematic account of the properties of the Stieltjes transform is given in [289, Chapter VIII]. Stieltjes functions are discussed by van Herk [284] as class ¹F º in the wider context of moment and complex interpolation problems, see also the Comments 6.12, 7.16. Van Herk uses the integral representation Z 1 .ds/ s C sz Œ0;1 1 which can be transformed by the change of variables t D s 1 1 2 Œ0; 1 for s 2 Œ0; 1 into the form (2.2); N .dt / and .ds/ are image measures under this transformation. Van Herk only observes that his class ¹F º contains S, but comparing [284, Theorem 7.50] with our result (7.2) in Chapter 7 below shows that ¹F º D S. In his paper [135] F. Hirsch introduces Stieltjes transforms into potential theory and identifies S as a convex cone operating on the abstract potentials, i.e. the densely defined inverses of the infinitesimal generators of C0 -semigroups. Hirsch establishes several properties of the cone S, which are later extended by Berg [22, 23]. A presentation of this material from a potential theoretic point of view is contained in the monograph [29, Chapter 14] by Berg and Forst, the connections to the moment problem are surveyed in [25]. Theorem 2.2 appears in Hirsch [135, Proposition 1], but with a different proof. In contrast to completely monotone functions, S is not closed under multiplication. This follows easily since the (necessarily unique) representing measure of 7! . C a/ 1 . C b/ 1 , 0 < a < b, is .b t / 1 ıa .dt / C .a t / 1 ıb .dt / which is a signed measure. We will see in Proposition 7.10 that S isRstill logarithmically convex. It is known, see Hirschman andRWidder [140, VII 7.4], that the R product .0;1/ . C t / 1 1 .dt / .0;1/ . C t / 1 2 .dt / is of the form .0;1/ . C t / 2 .dt / for some measure . The latter integral is often called a generalized Stieltjes transform. The following related result is due to Srivastava and Tuan [264]: if f 2 Lp .0; 1/ and g 2 Lq .0; 1/ with 1 < p; q < 1 and r 1 D p 1 C q 1 < 1, then there is some h 2 Lr .0; 1/ such that L 2 .f I /L 2 .gI / D L 2 .hI / holds. Since Z 1 Z 1 f .u/ g.u/ h.t / D f .t / p.v. du C g.t / p.v. du; u t u t 0 0 h will, in general, change its sign even if f; g are non-negative.
Chapter 3
Bernstein functions
We are now ready to introduce the class of Bernstein functions which are closely related to completely monotone functions. The notion of Bernstein functions goes back to the potential theory school of A. Beurling and J. Deny and was subsequently adopted by C. Berg and G. Forst [29], see also [25]. S. Bochner [50] calls them completely monotone mappings (as opposed to completely monotone functions) and probabilists still prefer the term Laplace exponents, see e.g. Bertoin [36, 38]; the reason will become clear from Theorem 5.2. Definition 3.1. A function f W .0; 1/ ! R is a Bernstein function if f is of class C 1 , f ./ > 0 for all > 0 and . 1/n 1 f .n/ ./ > 0
for all n 2 N and > 0:
(3.1)
The set of all Bernstein functions will be denoted by BF. It is easy to see from the definition that, for example, the fractional powers 7! ˛ , are Bernstein functions if, and only if, 0 6 ˛ 6 1. The key to the next theorem is the observation that a non-negative C 1 -function f W .0; 1/ ! R is a Bernstein function if, and only if, f 0 is a completely monotone function. Theorem 3.2. A function f W .0; 1/ ! R is a Bernstein function if, and only if, it admits the representation Z f ./ D a C b C
.1
e
t
/ .dt/;
(3.2)
.0;1/
R where a; b > 0 and is a measure on .0; 1/ satisfying .0;1/ .1 ^ t/ .dt/ < 1. In particular, the triplet .a; b; / determines f uniquely and vice versa.
Remark 3.3. (i) The representing measure and the characteristic triplet .a; b; / from (3.2) are often called the Lévy measure and the Lévy triplet of the Bernstein function f . The formula (3.2) is called the Lévy–Khintchine representation of f .
16
3 Bernstein functions
(ii) A useful variant of the representation formula (3.2) can be obtained by an application of Fubini’s theorem. Since Z Z Z t .1 e / .dt/ D e s ds .dt/ .0;1/
Z
.0;1/ 1Z
D
.0;t/
e 1
Z
.dt/ ds
.s;1/
0
D
s
s
e
.s; 1/ ds
0
we get that any Bernstein function can be written in the form Z f ./ D a C b C
e
s
M.s/ ds
(3.3)
.0;1/
where M.s/ D M .s/ D .s; 1/ is a non-increasing, right-continuous R1 R 1 function. Integration by parts and the observation that 0 se s ds D 2 and 0 e s ds D 1 yield Z 2 f ./ D e s k.s/ ds D 2 L .kI / (3.4) .0;1/
Rs
with k.s/ D as C b C 0 M.t/ dt, compare with Theorem 6.2(iii). Note that k is positive, non-decreasing and concave. R (iii) The integrability condition .0;1/ .1 ^ t/ .dt/ < 1 ensures that the integral in (3.2) converges for some, hence all, > 0. This is immediately seen from the convexity inequalities t 61 1Ct
e
t
61^t 62
t ; 1Ct
t >0
and the fact that for > 1 [respectively for 0 < < 1] and all t > 0 1 ^ t 6 1 ^ .t/ 6 .1 ^ t/
respectively .1 ^ t/ 6 1 ^ .t/ 6 1 ^ t :
(iv) A useful consequence of the above estimate and the representation formula (3.2) are the following formulae to calculate the coefficients a and b: a D f .0C/ and
f ./ : !1
b D lim
The first formula is obvious while the second follows from (3.2) and the dominated convergence theorem: 1 e t 6 1 ^ .t/ and lim!1 .1 e t /= D 0.
3 Bernstein functions
(v) Formula (3.3) shows, in particular, that Z 1 Z .t; 1/ dt D 0
17
1
M.t/ dt < 1:
(3.5)
0
Since a non-increasing function which is integrable near zero is o.1=t/ as t ! 0, we conclude from (3.5) that lim t.t; 1/ D lim tM.t/ D 0:
t !0C
(3.6)
t !0C
Proof of Theorem 3.2. Assume that f is a Bernstein function. Then f 0 is completely monotone. According to Theorem 1.4, there exists a measure on Œ0; 1/ such that for all > 0 Z 0 f ./ D e t .dt/: Œ0;1/
Let b WD ¹0º. Then
Z f ./
f .0C/ D
f 0 .y/ dy D b C
Z
Z
0
0
yt
e t
t
.dt/ dy
.0;1/
Z D b C
e 1 .0;1/
.dt/:
Write a WD f .0C/ and define .dt/ WD t 1 j.0;1/ .dt/. Then the calculation from above shows that (3.2) is true. That a; b > 0 is obvious, and from the elementary (convexity) estimate .1
1
e
we infer Z .0;1/
.1 ^ t/ .dt/ 6
/.1 ^ t/ 6 1
e e
Z 1
.1 .0;1/
e t;
t > 0;
e t / .dt/ D
e e
1
f .1/ < 1:
Conversely, suppose that f is given by (3.2) with .a; b; / as in the statement of the theorem. Since te t 6 t ^ .e/ 1 , we can apply the differentiation lemma for parameter-dependent integrals for all from Œ; 1 and all > 0. Differentiating (3.2) under the integral sign yields Z Z 0 t f ./ D b C e t .dt/ D e t .dt/; .0;1/
Œ0;1/
where .dt/ WD t.dt/ C bı0 .dt/. This formula shows that f 0 is a completely monotone function. Therefore, f is a Bernstein function. Because f .0C/ D a and because of the uniqueness assertion of Theorem 1.4 it is clear that .a; b; / and f 2 BF are in one-to-one correspondence.
18
3 Bernstein functions
The derivative of a Bernstein function is completely monotone. The converse is only true, if the primitive of a completely monotone function is positive. This fails, for example, for the completely monotone function 2 whose primitive, 1 , is not a Bernstein function. The next proposition characterizes the image of BF under differentiation. R Proposition 3.4. Let g./ D b C .0;1/ e t .dt/ be a completely monotone function. It has a primitive f 2 BF if, and only if, the representing measure satisfies R 1 .dt/ < 1. .0;1/ .1 C t/ Proof. Assume that f is a Bernstein function given in the form (3.2). Then Z 0 f ./ D b C e t t .dt/ .0;1/
is completely monotone and the measure .dt/ WD t.dt/ satisfies Z Z Z 1 t .dt/ D .dt/ 6 .1 ^ t/ .dt/ < 1: .0;1/ 1 C t .0;1/ 1 C t .0;1/ R Retracing the above steps reveals that .0;1/ .1 C t/ 1 .dt/ < 1 is also sufficient R to guarantee that g./ WD b C .0;1/ e t .dt/ has a primitive which is a Bernstein function. Theorem 3.2 allows us to extend Bernstein functions onto the right complex half! plane H WD ¹z 2 C W Re z > 0º. ! ! Proposition 3.5. Every f 2 BF has an extension f W H ! H which is continuous for Re z > 0 and holomorphic for Re z > 0. Proof. The function 7! 1 e t appearing in (3.2) has a unique holomorphic extension. If z D C i is such that D Re z > 0 we get ˇZ zt ˇ ˇ ˇ zt ˇ j1 e j D ˇ e d ˇˇ 6 tjzj and j1 e zt j 6 1 C je zt j 6 2: 0
! This means that (3.2) converges uniformly in z 2 H and f .z/ is well defined and ! holomorphic on H. Moreover, Z Re f .z/ D a C bRe z C Re .1 e zt / .dt/ Z .0;1/ D a C b C 1 e t cos.t/ .dt/ .0;1/
which is positive since D Re z > 0 and 1
e
t
cos.t/ > 1
e
t
> 0.
3 Bernstein functions
Continuity up to the boundary follows from the estimate Z jf .z/ f .w/j 6 bjz wj C je wt e .0;1/
zt
19
j .dt/
Z 6 bjz
wj C
.0;1/
2 ^ .tjw
zj/ .dt/
! for all z; w 2 H and the dominated convergence theorem. The following structural characterization comes from Bochner [50, pp. 83–84] where Bernstein functions are called completely monotone mappings. Theorem 3.6. Let f be a positive function on .0; 1/. Then the following assertions are equivalent. (i) f 2 BF. (ii) g ı f 2 CM for every g 2 CM. (iii) e
uf
2 CM for every u > 0.
Proof. The proof relies on the following formula for the n-th derivative of the composition h D g ı f due to Faa di Bruno [93], see also [111, formula 0.430]: !ij ` X Y f .j / ./ nŠ .n/ .m/ h ./ D g (3.7) f ./ i1 Š i` Š jŠ j D1
.m;i1 ;:::;i` /
where
P
.m;i1 ;:::;i` / stands for summation over P P that j`D1 j ij D n and j`D1 ij D m.
all ` 2 N and all i1 ; : : : ; i` 2 N [ ¹0º
such (i))(ii) Assume that f 2 BF and g 2 CM. Then h./ D g.f .// > 0. Multiply P formula (3.7) by . 1/n and observe that n D m C j`D1 .j 1/ ij . The assumptions f 2 BF and g 2 CM guarantee that each term in the formula multiplied by . 1/n is non-negative. This proves that h D g ı f 2 CM. (ii))(iii) This follows from the fact that g./ WD gu ./ WD e u , u > 0, is completely monotone. P j j (iii))(i) The series e uf ./ D j1D0 . 1/j Š u Œf ./j and all of its formal derivan
d tives (w.r.t. ) converge uniformly, so we can calculate d ne uf ferentiation. Since e is completely monotone, we get
dn 0 6 . 1/ e d n n
uf ./
D
1 X uj j D1
jŠ
. 1/nCj
Dividing by u > 0 and letting u ! 0 we see 0 6 . 1/nC1
dn f ./: d n
uf ./
by termwise dif-
j dn f ./ : d n
20
3 Bernstein functions
Theorems 3.2 and 3.6 have a few important consequences. Corollary 3.7. (i) The set BF is a convex cone: if f1 ; f2 2 BF, then sf1 Ctf2 2 BF for all s; t > 0. (ii) The set BF is closed under pointwise limits: if .fn /n2N BF and if the limit limn!1 fn ./ D f ./ exists for every > 0, then f 2 BF. (iii) The set BF is closed under composition: if f1 ; f2 2 BF, then f1 ı f2 2 BF. In particular, 7! f1 .c/ is in BF for any c > 0. (iv) For all f 2 BF the function 7! f ./= is in CM. (v) f 2 BF is bounded if, and only if, in (3.2) b D 0 and .0; 1/ < 1. (vi) Let f1 ; f2 2 BF and ˛; ˇ 2 .0; 1/ such that ˛ C ˇ 6 1. Then 7! f1 .˛ /f2 .ˇ / is again a Bernstein function. Proof. (i) This follows immediately from Definition 3.1 or, alternatively, from the representation formula (3.2). (ii) For every u > 0 we know that e ufn is a completely monotone function and that e uf ./ D limn!1 e ufn ./ . Since CM is closed under pointwise limits, cf. Corollary 1.6, e uf is completely monotone and f 2 BF. (iii) Let f1 ; f2 2 BF. For any g 2 CM we use the implication (i))(ii) of Theorem 3.6 to get g ı f1 2 CM, and then g ı .f1 ı f2 / D .g ı f1 / ı f2 2 CM. The converse direction (ii))(i) of Theorem 3.6 shows that f1 ı f2 2 BF. R 1 s t (iv) Note that .1 e /= D 0 e ds is completely monotone. Therefore, a f ./ D CbC
Z
1 .0;1/
e
t
.dt/
is the limit of linear combinations of completely monotone functions which is, by Corollary 1.6, completely monotone. (v) That b D 0 and .0; 1/ < 1 imply the boundedness of f is clear from the representation (3.2). Conversely, if f is bounded, b D 0 follows from Remark 3.3(iv), and .0; 1/ < 1 follows from (3.2) and Fatou’s lemma. (vi) We know that the fractional powers 7! ˛ , 0 6 ˛ 6 1, are Bernstein functions. Since h./ WD f1 .˛ /f2 .ˇ / is positive, it is enough to show that the derivative h0 is completely monotone. We have h0 ./ D ˛f10 .˛ /˛ D
˛Cˇ 1
1
f2 .ˇ / C ˇf20 .ˇ /ˇ
˛f10 .˛ /
1
f1 .˛ /
! ˛ f2 .ˇ / 0 ˇ f1 . / C ˇf2 . / : ˛ ˇ
Note that f10 ./; f20 ./ and, by part (iv), 1 f1 ./; 1 f2 ./ are completely monotone. By Theorem 3.6(ii) the functions f10 .˛ /; f20 .ˇ /; f1 .˛ /=˛ and f2 .ˇ /=ˇ
3 Bernstein functions
21
are again completely monotone. Since ˛ C ˇ 6 1, 7! ˛Cˇ 1 is completely monotone. As sums and products of completely monotone functions are in CM, see Corollary 1.6, h0 is completely monotone. Just as for completely monotone functions, the closure assertion of Corollary 3.7 says that on the set BF the notions of pointwise convergence, locally uniform convergence, and even convergence in the space C 1 coincide. Corollary 3.8. Let .fn /n2N be a sequence of Bernstein functions such that the limit limn!1 fn ./ D f ./ exists for all 2 .0; 1/. Then f 2 BF and for all k 2 N [ .k/ ¹0º the convergence limn!1 fn ./ D f .k/ ./ is locally uniform in 2 .0; 1/. If .an ; bn ; n / and .a; b; / are the Lévy triplets for fn and f , respectively, see (3.2), we have lim n D vaguely in .0; 1/;
n!1
and a D lim lim inf an C n ŒR; 1/ ; R!1 n!1
t n .dt/ :
Z
b D lim lim inf bn C !0 n!1
.0;/
In both formulae we may replace lim infn by lim supn . Proof. From Corollary 3.7(ii) we know that f 2 BF. Obviously, limn!1 e fn D e f ; by Theorem 3.6, the functions e fn ; e f are completely monotone and we can use Corollary 1.7 to conclude that e
fn n!1
!e
f
and . fn0 / e
fn n!1
! . f 0/ e
f
locally uniformly on .0; 1/. In particular, limn!1 fn0 ./ D f 0 ./ for each 2 .0; 1/. Again by Corollary 1.7 and the complete monotonicity of fn0 ; f 0 we see that .k/ for k > 1 the derivatives fn converge locally uniformly to f .k/ . By the mean value theorem, jfn ./
f ./j D j log e
f ./
log e
fn ./
j 6 C je
f ./
e
fn ./
j
with C 6 e f ./Cfn ./ . The locally uniform convergence of e fn ensures that C is bounded for n 2 N and from compact sets in .0; 1/; this proves locally uniform convergence of fn to f on .0; 1/. Differentiating the representation formula (3.2) we get Z Z fn0 ./ D bn C t e t n .dt/ D e t bn ı0 .dt/ C t n .dt/ ; .0;1/
Œ0;1/
implying that bn ı0 .dt/Ct n .dt/ converge vaguely to bı0 .dt/Ct .dt/. This proves at once that n ! vaguely on .0; 1/ as n ! 1.
22
3 Bernstein functions
Since bn ı0 .dt/ C t n .dt/ converge vaguely to bı0 .dt/ C t .dt/, we can use the portmanteau theorem, Theorem A.7, to conclude that Z Z t n .dt/ D b C t .dt/ lim bn C n!1
.0;/
.0;/
at all continuity points > 0 of . If j > 0 is a sequence of continuity points of such that j ! 0, we get Z t n .dt/ : b D lim lim bn C j !1 n!1
.0;j /
For a sequence of arbitrary j ! 0 we find continuity points ıj ; j , j 2 N, of such that 0 < ıj 6 j 6 j and ıj ; j ! 0. Thus, Z Z Z t n .dt/; t n .dt/ 6 bn C bn C t n .dt/ 6 bn C .0;j /
.0;j /
.0;ıj /
and we conclude that Z lim lim bn C j !1 n!1
.0;ıj /
t n .dt/
Z
t n .dt/ 6 lim lim inf bn C j !1 n!1
.0;j /
Z 6 lim lim sup bn C j !1 n!1
Z 6 lim lim bn C j !1 n!1
t n .dt/ .0;j /
t n .dt/ : .0;j /
Since both sides of the inequality coincide, the claim follows. Using a D f .0C/ we find for each R > 1 a D lim f ./ !0
D lim lim fn ./ !0 n!1 Z D lim lim an C bn C !0 n!1
Z D lim lim an C !0 n!1
.1
e
t
/ n .dt/
.0;1/
.1 ŒR;1/
e
t
Z / n .dt/ C bn C
.1
e
t
/ n .dt/ :
.0;R/
From the convexity estimate .1
e
1
/.1 ^ t/ 6 .1
e t /;
t > 0;
we obtain .1
e
t
/ 1.0;R/ .t/ 6 t 1.0;R/ .t/ 6 .t ^ R/ 6 R.1 ^ t/ 6 R
.1 .1
e t/ e 1/
3 Bernstein functions
23
so that Z bn C
.1 .0;R/
e
t
R / n .dt/ 6 bn C .1 e 1 / 6
.1
Since limn!1 fn .1/ D f .1/, we get Z a D lim lim an C !0 n!1
Z .1
e t / n .dt/
.0;R/
R fn .1/: e 1/
.1
e
t
/ n .dt/ :
ŒR;1/
For any continuity point R > 1 of , we have by vague convergence Z Z !0 t e t .dt/ ! ŒR; 1/ lim e n .dt/ D n!1 ŒR;1/
ŒR;1/
R!1
! 0:
Letting R ! 1 through a sequence of continuity points Rj , j 2 N, of we get a D lim lim an C n ŒRj ; 1/ : j !1 n!1
That we do not need to restrict ourselves to continuity points Rj follows with a similar argument as for the coefficient b. Example 3.9. The proof of Corollary 3.8 shows that the vague limit does not capture the accumulation of mass at D 0 and D 1 of the n as n ! 1. These effects can cause the appearance of a > 0 and b > 0 in the Lévy triplet of the limiting function f , even if an D bn D 0 for all functions fn . Here are two extreme cases: fn ./ D n.1
e
=n
/
n!1
! D f ./;
i.e. .an ; bn ; n / D .0; 0; nı1=n / and .a; b; / D .0; 1; 0/, and fn ./ D 1
e
n n!1
! 1 D f ./
where .an ; bn ; n / D .0; 0; ın / and .a; b; / D .1; 0; 0/. There is a one-to-one correspondence between bounded Bernstein functions and bounded completely monotone functions. Proposition 3.10. If g 2 CM is bounded, then g.0C/ g 2 BF. Conversely, if f 2 BF is bounded, there exist some constant c > 0 and some bounded g 2 CM, lim!1 g./ D 0, such that f D c g. The constant can be chosen to be c D f .0C/ C g.0C/.
24
3 Bernstein functions
Proof. Assume that g D L 2 CM is bounded. This means that .0; R 1/ D g.0C/ D sup>0 g./ < 1. Hence, f ./ WD g.0C/ g./ D .0;1/ .1 e t / .dt/ is a bounded Bernstein function. R Conversely, if f 2 BF is bounded, f ./ D a C .0;1/ .1 e t /.dt/ for some bounded measure , cf. Corollary 3.7. Thus f ./ D c g./ where g./ D L .I / is completely monotone, lim!1 g./ D 0 and c D a C .0; 1/ D f .0C/ C g.0C/ > 0. Remark 3.11. Just as in the case of completely monotone functions, see Remark 1.8, we can understand the representation formula (3.2) as a particular case of a Kre˘ın– Milman or Choquet representation. The set ² ³ Z f 2 BF W f ./e d D 1 .0;1/
is a basis of the convex cone BF, and its extremal points are given by 1Ct .1 e t /; 0 < t < 1; and e1 ./ D 1; t see Harzallah [122] or [251, Satz 2.9]. These functions are, of course, examples and building blocks for all Bernstein functions: every f 2 BF can be written as an ‘integral mixture’ of the above extremal Bernstein functions. If we choose .dt/ D ˛= .1 ˛/ t 1 ˛ dt , ˛ 2 .0; 1/, .dt/ D e t , or .dt/ D t 1 e t we see that the functions or log.1 C / ˛ .0 < ˛ < 1/; or 1C are Bernstein functions. e0 ./ D ;
e t ./ D
Comments 3.12. The name Bernstein function is not universally accepted in the literature. It originated in the potential theory school of A. Beurling and J. Deny, but the name as such does not appear in Beurling’s or Deny’s papers. The earliest mentioning of Bernstein functions as well as a nice presentation of their properties is Faraut [95]. Bochner [50] calls Bernstein functions completely monotone mappings but this notion was only adopted in the 1959 paper by Woll [292]. Other names include inner transformations of CM (Schoenberg [255]), Laplace or subordinator exponents (Bertoin [36, 38]), log-Laplace transforms or positive functions with completely monotone derivative (Feller [100]). Bochner pointed out the importance of Bernstein functions already in [49] and [50]; he defines them through the equivalent property (ii) of Theorem 3.6. The equivalence of (i) and (ii) in Theorem 3.6 is already present in Schoenberg’s paper [255, Theorem 8]; Schoenberg defines Bernstein functions as primitives of completely monotone functions and calls them inner transformations (of completely monotone functions); his notation is T for the class BF. Many properties as well as higher-dimensional analogues are given in [50, Chapter 4]. In particular, Theorems 3.2 and 3.6 can already be found there. An up-to-date account is given in the books by Berg and Forst [29, Chapter 9] (based on [95]) and Berg, Christensen and Ressel [28]. One can understand (3.2) as a Lévy–Khintchine formula for the semigroup .Œ0; 1/; C/. This justifies the name Lévy measure and Lévy triplet for and .a; b; /, respectively; this point of view is taken in [28]. The representation (3.4) is taken from Prüss [240, Chapter I.4.1] who calls the functions k.s/ (of the type needed in (3.4), i.e. positive, non-decreasing and concave) creep functions. The characterization of Bernstein functions using Choquet’s representation is due to Harzallah [120, 121, 122], a slightly different version is given in [251], reprinted in [157, Theorem 3.9.20].
Chapter 4
Positive and negative definite functions
Positive and negative definite functions appear naturally in connection with Fourier analysis and potential theory. In this chapter we will see that (bounded) completely monotone functions correspond to continuous positive definite functions on .0; 1/ and that Bernstein functions correspond to continuous negative definite functions on the half-line. On Rd the notion of positive definiteness is familiar to most readers; for our purposes it is useful to adopt a more abstract point of view which includes both settings, Rd and the half-line Œ0; 1/. An abelian semigroup with involution .S; C; / is a nonempty set equipped with a commutative and associative addition C, a zero element 0 and a mapping W S ! S called involution, satisfying (a) .s C t/ D s C t for all s; t 2 S ; (b) .s / D s for all s 2 S . We are mainly interested in the semigroups .Œ0; 1/; C/ and .Rd ; C/ where ‘C’ is the usual addition; the respective involutions are the identity mapping s 7! s in Œ0; 1/ and the reflection at the origin 7! in Rd . We will only develop those parts of the theory that allow us to characterize CM and BF as positive and negative definite functions on the half-line. Good expositions of the general case are the monographs by Berg, Christensen, Ressel [28] (for semigroups) and Berg, Forst [29] (for abelian groups). Definition 4.1. A function f W S ! C is positive definite if n X
f .sj C sk / cj cNk > 0
(4.1)
j;kD1
holds for all n 2 N, all s1 ; : : : ; sn 2 S and all c1 ; : : : ; cn 2 C. We need some simple properties of positive definite functions. Lemma 4.2. Let f W S ! C be positive definite. Then f .s C s / > 0 for all s 2 S and f is hermitian, i.e. f .s / D f .s/. In particular, f .0/ > 0. Lemma 4.2 shows also that positive definite functions on Œ0; 1/ are non-negative: f > 0.
26
4 Positive and negative definite functions
Proof of Lemma 4.2. That f .s C s / > 0 follows immediately from (4.1) if we take n D 1 and s1 D s; f .0/ > 0 is now obvious. Again by (4.1) we see that the matrix .f .sj C sk // is (non-negative definite) hermitian. Thus we find with n D 2 and s1 D 0, s2 D s that > f .0/ f .s/ f .0/ f .s / f .s / f .0/ D D : f .s / f .s C s / f .s/ f .s C s / f .s/ f .s C s /
Comparing the entries of the matrices we conclude that f .s / D f .s/. Definition 4.3. A function f W S ! C is negative definite if it is hermitian, i.e. f .s / D f .s/, and if n X
f .sj / C f .sk /
f .sj C sk / cj cNk > 0
(4.2)
j;kD1
holds for all n 2 N, all s1 ; : : : ; sn 2 S and all c1 ; : : : ; cn 2 C. Note that ‘f is negative definite’ does not mean that ‘ f is positive definite’. The connection between those two concepts is given in the following proposition. Proposition 4.4 (Schoenberg). For a function f W S ! C the following assertions are equivalent. (i) f is negative definite. (ii) f .0/ > 0, f .s / D f .s/ and f is conditionally positive definite, i.e. for all P n 2 N, all s1 ; : : : ; sn 2 S and all c1 ; : : : ; cn 2 C satisfying jnD1 cj D 0 one has n X f .sj C sk / cj cNk 6 0: (4.3) j;kD1
(iii) f .0/ > 0 and s 7! e
tf .s/
is positive definite for all t > 0.
Proof. (i))(iii) The Schur (or Hadamard) product of two n n matrices A D .aj k / and B D .bj k / is the n n matrix C with entries aj k bj k . If A; B are non-negative definite hermitian matrices, then C is non-negative definite hermitian. Indeed, writing B D PP where P D .pj k / 2 Cnn and P is the adjoint matrix of P , we have bj k D
n X `D1
pj ` pNk` :
4 Positive and negative definite functions
27
For every choice of c1 ; : : : ; cn 2 C we get " n # n n X X X aj k bj k cj cNk D aj k .pj ` cj /.pk` ck / > 0: j;kD1
`D1
j;kD1
In particular, if .aj k / is a non-negative definite hermitian matrix, so is .exp.aj k //. If we apply this to the non-negative definite hermitian matrices f .sj / C f .sk / f .sj C sk / j;kD1;:::;n ; n 2 N; s1 ; : : : ; sn 2 C; we conclude that
exp f .sj / C f .sk /
f .sj C sk /
j;kD1;:::;n
is a non-negative definite hermitian matrix. This implies that for all c1 ; : : : ; cn 2 C n X
e
f .sj Csk /
cj cNk D
j;kD1
n X
e f .sj /Cf .sk /
f .sj Csk /
e f .sj /Cf .sk /
f .sj Csk /
e
f .sj /
e
f .sk /
cj cNk
j;kD1
D
n X
j Nk > 0;
j;kD1
where j WD cj e f .sj / 2 C. This proves that e f is positive definite. Replacing f by tf , t > 0, the same argument shows that e tf is positive definite. That f .0/ > 0 follows directly from the definition if we take n D 1, s1 D 0 and c1 D 1. P (iii))(ii) Let n 2 N, s1 ; : : : ; sn 2 S and c1 ; : : : ; cn 2 C with jnD1 cj D 0. Because of (iii) we see that for all t > 0 n X 1 1 t
e
tf .sj Csk /
cj cNk D
j;kD1
n X 1 e t
tf .sj Csk /
cj cNk 6 0:
j;kD1
Letting t ! 0 we obtain n X
f .sj C sk / cj cNk 6 0:
j;kD1
By Lemma 4.2, the functions e tf are hermitian and so is f D lim t !0 .1 e tf /=t . (ii))(i) We use (4.3) with P n C 1 instead of n and for 0; s1 ; : : : ; sn 2 S and n c; c1 ; : : : ; cn 2 C where c D kD1 ck . Then 2
f .0/jcj C
n X j D1
f .sj / cj cN C
n X j D1
f .sj / c cNj
C
n X j;kD1
f .sj C sk / cj cNk 6 0:
28
4 Positive and negative definite functions
Using the fact that f .sj / D f .sj / and inserting the definition of c, we can rewrite this expression and find n X
f .sj C sk / cj cNk > f .0/jcj2 > 0:
f .sj / C f .sk /
j;kD1
We will now characterize the bounded continuous positive definite and continuous negative definite functions on the semigroup .Œ0; 1/; C/ with involution D ; it will turn out that these functions coincide with the families CMb and BF, respectively. Since we are working on the closed half-line Œ0; 1/, it is useful to extend f 2 CMb or f 2 BF continuously to Œ0; 1/. Because of the monotonicity of f this can be achieved by f .0/ WD f .0C/ D lim f ./: !0
Note that this extension is unique and that, for a completely monotone function f , f .0C/ < 1 if, and only if, f is bounded. Throughout this chapter we will tacitly use this extension whenever necessary. Lemma 4.5. Let f 2 CMb . Then f is positive definite in the sense of Definition 4.1. Proof. From Theorem 1.4 we know that f 2 CMb is the Laplace transform of a finite measure on Œ0; 1/. Therefore, we find for all n 2 N, all 1 ; : : : ; n 2 Œ0; 1/ and all c1 ; : : : ; cn 2 C n n Z X X j t k t f .j C k /cj cNk D e e .dt/ cj cNk j;kD1
j;kD1
n X
Z D
Œ0;1/
Z D
Œ0;1/
! e
j t
cj e
k t c k
.dt/
j;kD1
ˇ n ˇX ˇ e ˇ
j t
Œ0;1/ j D1
ˇ2 ˇ cj ˇˇ .dt/ > 0:
Corollary 4.6. Let f 2 BF. Then f is negative definite in the sense of Definition 4.3. Proof. Let f 2 BF. From Theorem 3.6 we know that e tf 2 CM for all t > 0. Since e tf is bounded, we can use Lemma 4.5 to infer that (the unique extensions of) the functions e tf , t > 0, are positive definite, and we conclude with Proposition 4.4 that (the unique extension of) f is negative definite. We write a f ./ WD f . C a/ f ./ for the difference of step a > 0. The iterated differences of step sizes aj > 0, j D 1; : : : ; n, are defined by an : : : a1 f WD an .an
1
: : : a1 f /:
29
4 Positive and negative definite functions
Theorem 4.7. Every bounded continuous positive definite function f on .Œ0; 1/; C/ satisfies . 1/n an a1 f > 0 for all n 2 N; a1 ; : : : ; an > 0: (4.4) Proof. Assume that f is positive definite. Then f > 0. Taking n D 2 in (4.1) we see that the matrix f .2/ f . C a/ ; ; a > 0; f . C a/ f .2a/ is positive definite. Therefore its determinant is non-negative which implies p f . C a/ 6 f .2/ f .2a/; ; a > 0:
(4.5)
Applying (4.5) repeatedly, we arrive at f ./ 6 f 1=2 .0/ f 1=2 .2/ 6 f 3=4 .0/ f 1=4 .4/ 6 6 f 1
2
n
.0/ f 2
n
.2n /:
Since f is bounded, we can take the limit n ! 1 to get f ./ 6 f .0/;
> 0:
For N 2 N, c1 ; : : : ; cN 2 C and 1 ; : : : ; N > 0 we introduce an auxiliary function N X F .a/ WD f .a C ` C m / c` cNm : `;mD1
For all choices of n 2 N, b1 ; : : : ; bn 2 R and a1 ; : : : ; an > 0 we find n X
F .aj C ak / bj bNk D
j;kD1
n N X X
f .aj C ak C ` C m / bj bNk c` cNm
j;kD1 `;mD1
D
X
f .aj C ` / C .ak C m / .bj c` /.bk cm / > 0:
.j;`/;.k;m/
This proves that F is positive definite. Since f is bounded and continuous, so is F , and we conclude, as above, that F .a/ 6 F .0/. This amounts to saying that N X
f .` C m /
f .a C ` C m / cj cNm > 0;
`;mD1
i.e. the function a f is continuous and positive definite. Repeating the above argument shows that . 1/n an : : : a1 f is continuous and positive definite for all n 2 N and a1 ; : : : ; an > 0. Theorem 4.8 (Bernstein). For a measurable function f W .0; 1/ ! R the following conditions are equivalent.
30
4 Positive and negative definite functions
(i) f > 0 and . 1/n an : : : a1 f > 0 for all n 2 N and a1 ; : : : ; an > 0. (ii) There exists a non-negative measure on Œ0; 1/ such that Z f ./ D e t .dt/: Œ0;1/
(iii) f is infinitely often differentiable and . 1/n f .n/ > 0 for all n 2 N. Proof. (i))(ii) Denote by B.0; 1/ the real-valued Borel measurable functions on .0; 1/. Then ® C WD f 2 B.0; 1/ W f > 0 and . 1/n an : : : a1 f > 0 ¯ for all n 2 N and a1 ; : : : ; an > 0 is a convex cone. If we equip B.0; 1/ with the topology of pointwise convergence, its topological dual separates points. Since every f 2 C is non-increasing and nonnegative, the limit f .0C/ exists, and f is bounded if, and only if, f .0C/ < 1. For f 2 C the second differences are non-negative; in particular a a f > 0 which we may rewrite as f ./ C f . C 2a/ > 2f . C a/;
; a > 0:
This means that f is mid-point convex. Since f jŒc;d is finite on every compact interval Œc; d .0; 1/, we conclude that f j.c;d / is continuous for all d > c > 0, i.e. f is continuous, see for example Donoghue [83, pp. 12–13]. Define K WD ¹f 2 C W f .0C/ D 1º; this is a closed subset of C. Since it is contained in the set Œ0; 1.0;1/ \ B.0; 1/ which is, by Tychonov’s theorem, compact under pointwise convergence, it is also compact. Moreover, K is a basis of the cone Cb since for every f 2 Cb the normalized function f =f .0C/ 2 K. Now the Kre˘ın–Milman theorem applies and shows that K is the closed convex hull of its extreme points. For f 2 Cb we write f ./ D f . C a/ C f ./ f . C a/ D f . C a/ C . 1/a f ./: It follows directly from the definition of the set C that f . C a/ and a f are again in Cb . Thus, if f 2 K is extremal, both functions must be multiples of f . In particular, f . C a/ D c.a/f ./; > 0; a > 0: Letting ! 0 we see that f .a/ D c.a/. Since f .0C/ D 1 and since f is continuous, all solutions of the functional equation f . C a/ D f .a/f ./ are of the form f ./ D e t ./ D e t where t 2 Œ0; 1/. This means that the extreme points of K are contained in the set ¹e t W t > 0º. Since K is
4 Positive and negative definite functions
31
the closed convex hull of its extreme points, we conclude that there exists a measure supported in Œ0; 1/ such that Œ0; 1/ D 1 and Z f ./ D e t .dt/; f 2 K: Œ0;1/
This proves (ii) for f 2 Cb . By the uniqueness of the Laplace transform, see Proposition 1.2, the representing measure is unique. If f 2 C is not bounded, we argue as in the proof of Theorem 1.4. In this case, fa ./ WD f . C a/ is in Cb , and we find Z f . C a/ D e t a .dt/ for all a > 0: Œ0;1/
By the uniqueness of the representation, it is easy to see that the measure e at a .dt/ does not depend on a > 0. Writing .dt/ for e at a .dt/, we get the representation claimed in (ii) for all f 2 Cb . (ii))(iii) This is a simple application of the dominated convergence theorem, see for example the second part of the proof of Theorem 1.4. (iii))(i) By the mean value theorem we have for all a > 0 . 1/a f ./ D f ./
f . C a/ D
af 0 . C a/;
2 .0; 1/;
hence . 1/a f > 0. Iterating this argument yields . 1/n an : : : a1 f ./ D . 1/n a1 an f .n/ . C 1 a1 C C n an / for suitable values of 1 ; : : : ; n 2 .0; 1/. This proves (i). Corollary 4.9. The family CMb and the family of bounded continuous positive definite functions on .Œ0; 1/; C/ coincide. Proof. From Lemma 4.5 we know already that (the extension of) every f 2 CMb is positive definite. Conversely, if f is continuous and positive definite, Theorem 4.8 shows that f j.0;1/ is completely monotone. Since f is continuous, f .0C/ D f .0/ < 1 which implies the boundedness of f , because f is non-increasing and non-negative on .0; 1/. Corollary 4.10. The family BF and the family of continuous negative definite functions on .Œ0; 1/; C/ coincide. Proof. Lemma 4.6 shows that (the extension of) every f 2 BF is negative definite. Now let f be continuous and negative definite. Thus, for every t > 0 the (extension of the) function e tf is bounded, continuous and positive definite; by Corollary 4.9 it is in CMb , and by Theorem 3.6 we get f 2 BF.
32
4 Positive and negative definite functions
Let us briefly review the notion of positive and negative definiteness on the group .Rd ; C/. Our standard reference is the monograph [29] by Berg and Forst. On Rd the involution is given by D , 2 Rd . This means that f is positive definite (in the sense of Bochner) if n X
f .j
k / cj cNk > 0;
(4.6)
j;kD1
and negative definite (in the sense of Schoenberg) if n X
f .j / C f .k /
f .j
k / cj cNk > 0
(4.7)
j;kD1
hold for all n 2 N, 1 ; : : : ; n 2 Rd and c1 ; : : : ; cn 2 C. The Rd -analogue of Lemma 4.5 and Corollary 4.9 is known as Bochner’s theorem. Theorem 4.11 (Bochner). A function W Rd ! C is continuous and positive definite if, and only if, it is the Fourier transform of a finite measure on Rd , Z ./ D b ./ D e ix .dx/; 2 Rd : Rd
The measure is uniquely determined by , and vice versa. Lemma 4.6 and Corollary 4.10 become on Rd the Lévy–Khintchine representation. Theorem 4.12 (Lévy; Khintchine). A function W Rd ! C is continuous and negative definite if, and only if, there exist a number ˛ > 0, a vector ˇ 2 Rd , a symmetric and matrix Q 2 Rd d and a measure on Rd n ¹0º satisfying R positive semi-definite 2 y¤0 .1 ^ jyj / .dy/ < 1 such that Z 1 i y iy ./ D ˛ C iˇ C Q C 1 e C .dy/: (4.8) 2 1 C jyj2 y¤0 The quadruple .˛; ˇ; Q; / is uniquely determined by
, and vice versa.
Comments 4.13. Standard references for positive and negative definite functions are the monographs [28] by Berg, Christensen and Ressel and [29] by Berg and Forst. For a more probabilistic presentation we refer to Dellacherie and Meyer [77, Chapter X]. The natural notion of positive and negative definiteness of a (finite-dimensional) matrix was extended to functions by Mercer [213]. A function (or kernel) of positive type is a continuous and symmetric function W Œa; b Œa; b ! R satisfying Z bZ b .s; t / .s/.t / ds dt > 0 for all 2 C Œa; b: a
a
This condition is originally due to Hilbert [132] who refers to it as Definitheit (definiteness). It is shown in [213] that this is equivalent to saying that for all n 2 N and s1 ; : : : ; sn 2 R the matrices
4 Positive and negative definite functions
33
..sj ; sk // are non-negative definite hermitian, which is in accordance with Definition 4.1. Mercer says that is of negative type if is of positive type. Note that this does not match our definition of negative definiteness which appears first in Schoenberg [255] and, independently, in Beurling [41]; the name negative definite was first used by Beurling [42] in connection with bounded negative definite functions—these are all of the form c f where f is positive definite and c is a constant c > f .0/, see e.g. [29, 7.11–7.13]—while Definition 4.3 seems to appear first in Beurling and Deny [43]. The notion of a positive definite function was introduced by Mathias [210] and further developed by Bochner [48, Chapter IV.20] culminating in his characterization of all positive definite functions, Theorem 4.11. Note that, in general, a negative definite function is not the negative of a positive definite function— and vice versa. In order to avoid any confusion, many authors nowadays use ‘positive definite (in the sense of Bochner)’ and ‘negative definite (in the sense of Schoenberg)’. The abstract framework of positive (and negative) definiteness on semigroups is due to Ressel [243] and Berg, Christensen and Ressel [27]. Ressel observes that positive definiteness (in a semigroup sense) establishes the connection between two seemingly different topics: Fourier transforms and Bochner’s theorem on the one hand and, on the other, Laplace transforms, completely monotone functions and Bernstein’s theorem. Note that in the case of abelian groups there are always two choices for involutions: s WD s, which is natural for groups, and s D s which is natural for semigroups. Each leads to a different notion of positive and negative definiteness. The proof of Proposition 4.4 is adapted from [29, Chapter II.7] and [28, Chapters 4.3, 4.4]; for Theorems 4.7 and 4.8 we used Dellacherie–Meyer [77, X.73 and X.75] as well as Lax [199, Chapter 14.3]. The best references for continuous negative definite functions on Rd are [29, Chapter II] and [77, Chapter X].
Chapter 5
A probabilistic intermezzo
Completely monotone functions and Bernstein functions are intimately connected with vaguely continuous convolution semigroups of sub-probability measures on the half-line Œ0; 1/. The probabilistic counterpart of such convolution semigroups are subordinators—processes with stationary independent increments with state space Œ0; 1/ and right-continuous paths with left limits, i.e. Lévy processes with values in Œ0; 1/. In this chapter we are going to describe this connection which will lead us in a natural way to the concept of infinite divisibility and the central limit problem. Recall that a sequence .n /n2N of sub-probability measures on Œ0; 1/ converges vaguely to a measure if Z Z lim f .t/ n .dt/ D f .t/ .dt/ n!1 Œ0;1/
Œ0;1/
holds for every compactly supported continuous function f W Œ0; 1/ ! R, see Appendix A.1. The convolution of the sub-probability measures and on Œ0; 1/ is defined to be the sub-probability measure ? on Œ0; 1/ such that for every bounded continuous function f W Œ0; 1/ ! R, Z Z Z f .t/. ? /.dt/ D f .t C s/ .dt/.ds/: Œ0;1/
Œ0;1/
Œ0;1/
Definition 5.1. A vaguely continuous convolution semigroup of sub-probability measures on Œ0; 1/ is a family of measures . t / t >0 satisfying the following properties: (i) t Œ0; 1/ 6 1 for all t > 0; (ii) t Cs D t ? s for all t; s > 0; (iii) vague- lim t !0 t D ı0 . It follows immediately from (ii) and (iii) that vague- lim t!0 t Cs D s for all s > 0. Unless otherwise stated we will always assume that a convolution semigroup is vaguely continuous. For all 2 Cc Œ0; 1/ satisfying 0 6 6 1Œ0;1/ and .0/ D 1 we find Z Z t!0 1 > t Œ0; 1/ > .s/ t .ds/ ! .s/ ı0 .ds/ D 1: Œ0;1/
Œ0;1/
This proves lim t !0 t Œ0; 1/ D 1 D ı0 Œ0; 1/; from Theorem A.4 we conclude that in this case weak and vague continuity coincide.
5 A probabilistic intermezzo
35
Theorem 5.2. Let . t / t >0 be a convolution semigroup of sub-probability measures on Œ0; 1/. Then there exists a unique f 2 BF such that the Laplace transform of t is given by L t D e tf for all t > 0: (5.1) Conversely, given f 2 BF, there exists a unique convolution semigroup of subprobability measures . t / t >0 on Œ0; 1/ such that (5.1) holds true. Proof. Suppose that . t / t >0 is a convolution semigroup of sub-probability measures on Œ0; 1/. Fix t > 0. Since L t > 0, we can define a function f t W .0; 1/ ! R by f t ./ D log L . t I /. In other words, L . t I / D e
f t ./
:
By property (ii) of convolution semigroups, it holds that f tCs ./ D f t ./Cfs ./ for all t; s > 0, i.e. t 7! f t ./ satisfies Cauchy’s functional equation. Vague continuity ensures that this map is continuous, hence there is a unique solution f t ./ D tf ./ where f ./ D f1 ./. Therefore, L t D e
tf
for all t > 0I
in particular, e tf 2 CM for all t > 0. By Theorem 3.6, f 2 BF. Conversely, suppose that f 2 BF. Again by Theorem 3.6 we have that for all t > 0, e tf 2 CM . Therefore, for every t > 0 there exists a measure t on Œ0; 1/ such that L t D e tf . We check that the family . t / t >0 is a convolution semigroup of sub-probability measures. Firstly, t Œ0; 1/ D L . t I 0C/ D e tf .0C/ 6 1. Secondly, L . t ? s / D L t L s D e tf e sf D e .t Cs/f D L t Cs . By the uniqueness of the Laplace transform we get that t Cs D t ? s . Finally, lim t !0 L t ./ D lim t !0 e tf ./ D 1 D L ı0 ./ for all > 0 and, by Lemma A.9, vague- lim t !0 t D ı0 . Remark 5.3. Because of formula (5.1), probabilists often use the name Laplace exponent instead of Bernstein function. Definition 5.4. A stochastic process S D .S t / t>0 defined on a probability space .; F ; P/ with state space Œ0; 1/ is called a subordinator if it has independent and stationary increments, S0 D 0 a.s., and for almost every ! 2 , t 7! S t .!/ is a right-continuous function with left limits. The measures . t / t >0 defined by t .B/ D P.S t 2 B/;
B Œ0; 1/ Borel;
are called the transition probabilities of the subordinator S . Almost all paths t 7! S t .!/ of a subordinator S are non-decreasing functions.
36
5 A probabilistic intermezzo
Let ea be an exponential random variable with parameter a > 0, i.e. P.ea > t/ D e at , t > 0. We allow that a D 0 in which case ea D C1. Assume that ea is independent of the subordinator S . We define a process b S D .b S t / t >0 by ´ St ; t < ea ; b S t WD (5.2) C1; t > ea : The process b S is the subordinator S killed at an independent exponential time. Any process with state space Œ0; 1 having the same distribution as b S will be called a killed subordinator. The connection between (killed) subordinators and convolution semigroups of subprobability measures on Œ0; 1/ is as follows. For t > 0 let t .B/ WD P.Sbt 2 B/;
B Œ0; 1/ Borel;
be the transition probabilities of .b S t / t >0 , and note that Z St e y t .dy/ D L . t I /: EŒe b D Œ0;1/
Proposition 5.5. The family . t / t >0 is a convolution semigroup of sub-probability measures. Proof. We check properties (i)–(iii) in Definition 5.1. It is clear that t Œ0; 1/ 6 1. Let g W Œ0; 1/ ! R be a bounded continuous function. Then by the right-continuity of the paths, lim t !0 g.S t / D g.S0 / D g.0/ a.s. By the dominated convergence theorem it follows that lim t !0 EŒg.S t / D g.0/, i.e. Z Z lim g d t D g.0/ D g d ı0 ; t !0 Œ0;1/
Œ0;1/
thus proving property (iii). In order to show property (ii), assume first that a D 0, that is there is no killing. Then for s; t > 0, L .sCt I / D EŒe
SsCt
D EŒe D EŒe
.SsCt Ss / S t
EŒe
e
Ss
.Ss S0 /
(5.3)
D L . t I /L .s I /; which is equivalent to sCt D s ? t . If a > 0, we find by independence EŒe
b St
D EŒe
S t
1¹t<ea º D P.t < ea / EŒe
which, together with (5.3), concludes the proof.
S t
De
at
EŒe
S t
;
5 A probabilistic intermezzo
37
The converse of Proposition 5.5 is also true: given a convolution semigroup . t / t >0 of sub-probability measures on Œ0; 1/, there exists a killed subordinator .S t / t >0 on a probability space .; F ; P/ such that t D P.S t 2 / for all t > 0. A proof of this fact can be found in [36]. Let us rewrite (5.1) as EŒe
b St
tf ./
D L . t I / D e
Recall that f 2 BF has the representation Z f ./ D a C b C .1
e
t
:
/ .dt/:
.0;1/
It is clear from the proof of Theorem 5.2 that a D f .0C/ > 0 if, and only if, t Œ0; 1/ < 1 for all t > 0; in this case, the associated stochastic process has a.s. finite lifetime. This is why a is usually called the killing term of the Laplace exponent f . Let . t / t>0 be a convolution semigroup of sub-probability measures on Œ0; 1/ and let f be the corresponding Bernstein function. Then the completely monotone function g./ WD L .1 I / D e f ./ has the property that for every t > 0, g t is again completely monotone. This follows easily from g t ./ D e
tf ./
D L . t I /:
From the probabilistic point of view, thisP means that S t is an infinitely divisible random variable. To be more precise S t D jnD1 .Sjt=n S.j 1/t=n / for every n 2 N. The random variables .Sjt=n S.j 1/t=n /16j 6n are independent and identically distributed. Hence t D ?n is the n-fold convolution. This motivates the following t=n definition. Definition 5.6. A completely monotone function g is said to be infinitely divisible if for every t > 0 the function g t is again completely monotone. If g is infinitely divisible and g.0C/ 6 1, the sub-probability measure on Œ0; 1/ satisfying L D g is said to be an infinitely divisible distribution; we write 2 ID. The discussion preceding the definition shows that if f 2 BF, then g WD e f is completely monotone and infinitely divisible. Moreover, g.0C/ 6 1. This is already one direction of the next result. Lemma 5.7. Suppose that g W .0; 1/ ! .0; 1/. Then the following statements are equivalent. (i) g 2 CM, g is infinitely divisible and g.0C/ 6 1. (ii) g D e
f
where f 2 BF.
38
5 A probabilistic intermezzo
Proof. Suppose that (i) holds. Since g t 2 CM and clearly g t .0C/ 6 1, there exists a sub-probability measure t on Œ0; 1/ such that g t ./ D L . t I /. Since lim t !0 g t ./ D 1, it follows that vague- lim t !0 t D ı0 . For s; t > 0 it holds that g t g s D g t Cs , and consequently L . t I / L .s I / D L . t Cs I /: By the uniqueness of the Laplace transform this means that . t / t>0 is a convolution semigroup of sub-probability measures on Œ0; 1/. By Theorem 5.2, there exists a unique f 2 BF such that L . t I / D e tf ./ ; in particular, g D e f . Lemma 5.7 admits an extension to completely monotone functions g which need not satisfy g.0C/ 6 1. For the purpose of stating this extension, let us say that a C 1 function f W .0; 1/ ! R is an extended Bernstein function if . 1/n 1 f .n/ ./ > 0
for all n > 1 and > 0:
Note that a non-negative extended Bernstein function is actually a Bernstein function. Definition 5.8. A C 1 function g W .0; 1/ ! .0; 1/ is said to be logarithmically completely monotone if .log g/0 2 CM: (5.4) Theorem 5.9. Suppose that g W .0; 1/ ! .0; 1/. Then the following assertions are equivalent. (i) g 2 CM and g is infinitely divisible. (ii) g D e
f
where f is an extended Bernstein function.
(iii) g is logarithmically completely monotone. Proof. (i))(ii) For c > 0 let gc ./ WD g. C c/, > 0. Then 7!
gc ./ gc ./ D gc .0C/ g.c/
is again in CM, infinitely divisible and tends to 1 as ! 0. By Lemma 5.7, there exists fc 2 BF such that g. C c/ D gc ./ D g.c/e fc ./ for all > 0. This can be written as g./ D g.
c C c/ D g.c/e
fc . c/
De
fc . c/Clog g.c/
;
> c:
(5.5)
If 0 < b < c the same formula is valid with b replacing c. In particular, for 0 < b < c < it holds that fc .
c/ C log g.c/ D
fb .
b/ C log g.b/:
5 A probabilistic intermezzo
39
This implies that one can define a function f W .0; 1/ ! R by f ./ WD fc .
c/
log g.c/;
> c:
Clearly, f is C 1 on .0; 1/. For any > 0 find 0 < c < . By (5.5), g./ D e f ./ , .n/ and for n > 1, . 1/n 1 f .n/ ./ D . 1/n 1 fc . c/ > 0. Thus, f is an extended Bernstein function. (ii))(iii) If g D e f , then .log g/0 D f 0 and clearly f 0 2 CM. (iii))(i) Suppose g is logarithmically completely monotone. For c > 0, Cc
Z fc ./ WD
c
.log g/0 .t/ dt D
log g. C c/ C log g.c/;
> 0;
belongs to BF. Since g. C c/ D g.c/e fc ./ , it follows from Theorem 3.6 that 7! g. C c/ is in CM for all c > 0. Since g is continuous, we get that g./ D limc!0 g. C c/, hence g 2 CM. Note that g t is also logarithmically completely monotone for every t > 0, hence by the already proven fact, g t 2 CM. Thus, g is infinitely divisible. Remark 5.10. (i) The concept of infinite divisibility appears naturally in the central limit problem of probability theory. This problem can be stated in the following way: Let .Xn;j /j D1;:::;k.n/; n2N be a (doubly indexed) family of real random variables such that the random variables in each row, Xn;1 ; : : : ; Xn;k.n/ , are independent. When do the probability distributions Xn;1 C C Xn;k.n/ an law ; bn for suitably chosen sequences of real .an /n2N and positive .bn /n2N numbers, have a non-trivial weak limit as n ! 1? The classical example is, of course, the central limit theorem where a sequence of independent and identically distributed random variables .Xj /j 2N is arranged in a triangular array of the form X1 I
X1 ; X2 I
X1 ; X2 ; X3 I
:::
X1 ; X2 ; : : : ; Xn I
where k.n/ D n, an D n EX1 is the mean value and bn D deviation of the partial sum of the variables in the nth row.
p
:::
nVar X1 the standard
Clearly, every limiting random variable X is infinitely divisible in the sense that for every n 2 N there are independent copies Y1 ; : : : ; Yn such that X and Y WD Y1 C C Yn have the same probability distribution. The corresponding probability distributions are also called infinitely divisible.
40
5 A probabilistic intermezzo
It can be shown, see e.g. Gnedenko and Kolmogorov [108], that every infinitely divisible distrubition can be obtained as the limiting distribution of a triangular array .Xn;j /j D1;:::;k.n/;n2N , where each row Xn;1 ; : : : ; Xn;k.n/ consists of independent random variables which are asymptotically negligible, i.e. lim
max
n!1 16j 6k.n/
P.jXn;j j > / D 0
for all > 0:
(ii) Specializing to one-sided distributions supported in Œ0; 1/ we can express the property 2 ID in terms of the Laplace transform. By Lemma 5.7, g 2 CM with g.0C/ 6 1 is infinitely divisible if, and only if, for every n 2 N there is some gn 2 CM such that g D gnn . In probabilistic terms this means that the law 2 ID has an nth convolution root n such that L n D gn and D n?n . If X denotes a random variable with distribution and Yj , 1 6 j 6 n, denote independent and identically distributed random variables with the common distribution n , this means that X and Y1 C C Yn have the same probability distribution. Depending on the structure of the triangular array, the limiting distributions may have different stability properties. We will discuss this for one-sided distributions supported in Œ0; 1/. Often it is easier to describe them in terms of the corresponding Laplace transforms. Definition 5.11. A completely monotone function g 2 CM with g.0C/ 6 1 is said to be (weakly) stable if for all a > 0 there are b > 0; c > 0 such that g./a D g.c/ e
b
I
(5.6)
if b D 0 we call g strictly stable. The corresponding random variables and sub-probability distributions are also called (weakly or strictly) stable. We will see below in Proposition 5.13 that the constant c appearing in (5.6) is necessarily of the form c D a1=˛ for some ˛ 2 Œ0; 1; ˛ is often called the index of stability. It can be shown, cf. [108], that every stable is the limiting distribution of a sequence of independent and identically distributed random variables .Xj /j 2N and suitable centering and norming sequences .an /n2N , an > 0, and .bn /n2N , bn > 0: 11 0 0 n X 1 weak Xj an AA law @ @ ! : (5.7) n!1 bn j D1
All (weakly) stable distributions on Œ0; 1/ have Laplace transforms given by g./ D exp. ˇ˛ / with ˛ 2 Œ0; 1 and ˇ; > 0. The distributions are (strictly) stable if D 0.
5 A probabilistic intermezzo
41
If the Xj are only independent and if limn!1 bn D 1 and limn!1 bnC1 =bn D 1, then the limit (5.7) characterizes all self-decomposable (also: class L) distributions; we write 2 SD. Again we focus on one-sided distributions where we can express self-decomposability conveniently in terms of Laplace transforms. Definition 5.12. A completely monotone function g 2 CM with g.0C/ 6 1 is said to be self-decomposable, if 7!
g./ D gc ./ is completely monotone for all c 2 .0; 1/: g.c/
(5.8)
We will see in Proposition 5.15 that the Laplace exponent f of a 2 SD, i.e. L D e f , is a Bernstein function with a Lévy triplet of the form .a; b; m.t/ dt/ such that t 7! t m.t/ is non-increasing. The rather deep limit theorems—or the equally difficult structure results on the completely monotone functions—of Remark 5.10 show that ¹stable lawsº SD ID. The following two results contain a simple, purely analytic proof for this. Proposition 5.13. Let g 2 CM, g.0C/ 6 1, be (weakly) stable. Then there exist ˛ 2 Œ0; 1 and ˇ; > 0 such that g./ D e
ˇ˛
:
In particular, g.0C/ D 1. In the strictly stable case, D 0. Proof. The function 7! g.c/e b appearing in (5.6) is a product of two completely monotone functions, hence itself completely monotone. Thus, for every a > 0, g a 2 CM, which means that g is infinitely divisible. By Lemma 5.7, there exists some f 2 BF such that g D e f . The structure equation (5.6) becomes, in terms of f , for all a > 0 there are c > 0; b > 0 such that af ./ D f .c/ C b:
(5.9)
This implies that f .0C/ D 0. Differentiating this equality twice yields af 00 ./ D c 2 f 00 .c/:
(5.10)
In the trivial case where f 00 0 we have f ./ D for a suitable integration constant > 0, and we are done. In all other cases, (5.10) shows that c is a function of a only and that it does not depend on b. Indeed, if both .a; c/ and .a; c/ Q satisfy (5.9), we find from (5.10) with D 1=cQ c 2 00 c f D f 00 .1/: cQ 2 cQ As f 00 is increasing and non-trivial, it is easy to see that c D cQ and c D c.a/. Setting D 1 in (5.9) we see that b D af .1/ f .c/ is also unique. Since the inverse f 1 of
42
5 A probabilistic intermezzo
a non-trivial, i.e. non-constant, Bernstein function is again a continuous function, we get from (5.9) 1 c D c.a/ D f 1 af ./ b I this proves that c D c.a/ depends continuously on a > 0. For any two a; aQ > 0 we can use (5.10) twice to find 00 aaf Q 00 ./ D ac 2 .a/f Q 00 c.a/ Q D c 2 .a/af Q c.a/ Q D c 2 .a/c Q 2 .a/f 00 c.a/c.a/ Q : On the other hand, aaf Q 00 ./ D c 2 .aa/f Q 00 .c.aa//, Q so that c.aa/ Q D c.a/c.a/. Q Since c.a/ is continuous, there exists some ˛ 2 R such that c.a/ D a1=˛ . Inserting this into (5.10) we have 2 1 f 00 ./ D a ˛ 1 f 00 .a ˛ / for all a; > 0: Now take a D ˛ to get f 00 ./ D ˛ 2 f 00 .1/ and integrate twice. Using that f .0C/ D 0 we find f 00 .1/ ˛ f ./ D C f 00 .1/ C ˛.˛ 1/ with some integration constant C 2 R. Since f 2 BF is non-trivial, we know that 0 < ˛ 6 1. Finally, we can use (5.9) to work out that f 00 .1/ C D b=.a a1=˛ /. Corollary 5.14. We have ¹stable lawsº SD ID. Proof. The first inclusion follows from Proposition 5.13. If g is (weakly) stable, f ./ WD log g./ D ˇ˛ C . Thus, for 0 < c < 1, f ./
f .c/ D ˇ.1
c ˛ / ˛ C .1
c/
is a Bernstein function, and we get that gc ./ D g./=g.c/ D exp. .f ./ f .c/// is completely monotone. If (5.8) holds for g and all 0 < c < 1, we have g 0 ./ g.c/ g./ 1 g./ D lim D lim 1 : c!1 .1 c!1 .1 g./ c/g.c/ c/ g.c/ Since g./=g.c/ is bounded by 1 and completely monotone, the expression inside the brackets is a Bernstein function by Proposition 3.10. Dividing by makes it completely monotone, cf. Corollary 3.7(iv). Since limits of completely monotone functions are again completely monotone, cf. Corollary 1.7, we know that g is logarithmically completely monotone, hence infinitely divisible by Theorem 5.9. Proposition 5.15. Let 2 SD and let f 2 BF satisfy L D e f . Then the Lévy measure of f has a density m.t / such that t 7! t m.t/ is non-increasing.
5 A probabilistic intermezzo
43
Proof. Set g WD L , and for c 2 .0; 1/, gc ./ WD g./=g.c/. Since g./ D e f ./ , we have that gc ./ D exp. .f ./ f .c///. We will now show that gc is for each c 2 .0; 1/ logarithmically completely monotone. For this we have to check that gc0 =gc 2 CM. A small change in the proof of Corollary 5.14 shows that ./ WD
g 0 ./ g.c/ g./ 1 D lim D lim 1 c!1 .1 c!1 .1 g./ c/g.c/ c/
g./ g.c/
is a Bernstein function and, therefore, 0 is completely monotone. Moreover, d g./ d g.c/ g./ g.c/
gc0 ./ D gc ./
g 0 ./g.c/ g./cg 0 .c/ g.c/ g 2 .c/ g./
D
g 0 ./ cg 0 .c/ C g./ g.c/ Z Z 1 1 0 D .s/ ds D 0 .t/ dt: c c D
Thus, gc0 =gc is an integral mixture of completely monotone functions and as such, see Corollary 1.6, itself completely monotone. Now define fc ./ WD f ./ f .c/; by Theorem 5.9, fc 2 BF. Let Z f ./ D a C b C
.1
e
t
.0;1/
1
Z / .dt/ D a C b C
e
t
t
/ .c/ .dt/;
M.t/ dt;
0
where M.t/ D .t; 1/. Then fc ./ D f ./ f .c/ Z D a C b C
.1
t
e
/ .dt/
.0;1/
Z a C bc C
.1
e
c/ C
where .c/ ./ WD .c representation
1 /.
/ .dt/
.0;1/
Z D b.1
ct
.1
e
t
Z / .dt/
.1
.0;1/
e
.0;1/
On the other hand, fc being a Bernstein function, it has a
Q C fc ./ D b
Z .1 .0;1/
e
t
/ c .dt/:
44
5 A probabilistic intermezzo
Hence, c D .c/ , implying in particular that for every Borel set B .0; 1/ it holds that .B/ > .c 1 B/. For B D .s; t, this gives .s; t > .c 1 s; c 1 t for every c 2 .0; 1/. For s 2 R define h.s/ WD M.e s / D .e s ; 1/. Clearly, h is non-negative and non-decreasing. Moreover, we have for all u > 0 and c 2 .0; 1/ h.s C u/
h.s/ D M.e
s u
/
M.e
s
s u
/ D .e
;e
s
s u log c
> .e
;e
D h.s C u C log c/
s log c
h.s C log c/:
This shows that for all u > 0 the function s 7! h.s C u/ h.s/ is non-decreasing. Therefore, h is convex. Being non-negative, non-decreasing and convex, h can be written in the form Z s
h.s/ D
`.u/ du 1
where ` is non-negative and non-decreasing. Define k W .0; 1/ ! R by k.v/ WD `.e v /. Then k is non-negative and non-increasing. For t > 0 a change of variables shows Z log t Z 1 Z 1 `.e v / k.v/ M.t/ D h. log t/ D `.u/ du D dv D dv; v v 1 t t and the proof is finished by defining m.t/ WD k.t/=t . Now we define the potential measure of a vaguely continuous convolution semigroup . t / t >0 of sub-probability measures on Œ0; 1/. Notice that 1Z
Z
e 0
s
Œ0;1/
1
Z t .ds/ dt D
e
tf ./
dt D
0
1 : f ./
(5.11)
Since every continuous function u.s/ with compact support in Œ0; 1/ Rcan be domi1 nated by a multiple of e s , this implies that the vague integral U WD 0 t dt exists, see Remark A.3. U is called the potential measure of the convolution semigroup . t / t >0 or, equivalently, of the corresponding killed subordinator .S t / t >0 . Moreover, 1
Z U.A/ D
1
Z t .A/ dt D E
0
1¹S t 2Aº dt for all Borel sets A Œ0; 1/:
0
It is a simple consequence of Fubini’s theorem and (5.11) that L .U I / D
Z e Œ0;1/
s
1
Z
t .ds/ dt
0
D
1 ; f ./
(5.12)
5 A probabilistic intermezzo
45
where f 2 BF is the Bernstein function corresponding to the convolution semigroup . t / t >0 . This shows, in particular, that for all > 0 Z Z 2 1 > L .U I / D e t U.dt/ > e t U.dt/ > e U Œ0; ; Œ0;1/
Œ0;
proving that U is finite on bounded sets. In a similar way one defines for > 0 the -potential measure as the vague integral Z 1 U WD e t t dt: (5.13) 0
Definition 5.16. A function f W .0; 1/ ! .0; 1/ is said to be a potential if f D 1=g where g 2 BF D BF n ¹0º. The set of all potentials will be denoted by P. By (5.12), P consists of Laplace transforms of potential measures. In particular, P CM, and P consists of exactly those completely monotone functions f which have the property that 1=f 2 BF, i.e. ³ ² ³ ² 1 1 W f 2 BF D g 2 CM W 2 BF : (5.14) PD f g Proposition 5.17. Let g 2 P be a potential. Then g is logarithmically completely monotone and hence there exists an extended Bernstein function f such that g D e f . Proof. Let g 2 P. Then h D 1=g 2 BF and .log g/0 D .log h/0 D h0
1 D h0 g: h
Since both h0 and g are in CM, it follows that their product second part of the statement follows from Theorem 5.9.
.log g/0 2 CM. The
The converse does not hold. Indeed, f ./ D is a Bernstein function, so g./ WD e f ./ D e is logarithmically completely monotone. Since 1=g./ D e … BF, g is not a potential. Remark 5.18. Proposition 5.17 can be restated as follows. For every h 2 BF , there exists an extended Bernstein function f such that h D e f . In other words, log h is an extended Bernstein function. In Corollary 3.7(iii) we have proved that the set BF is closed under composition. Now we are going to give an alternative proof of this fact by explicitly producing the corresponding convolution semigroup. Suppose that . t / t >0 and . t / t >0 are two convolution semigroups on Œ0; 1/ with the corresponding Bernstein functions Z f ./ D a C b C .1 e t / .dt/ .0;1/
46
5 A probabilistic intermezzo
and Z g./ D ˛ C ˇ C
.1
e
t
/ .dt/:
.0;1/
Let us define a new family of measures . t / t >0 by Z t .dr/ D s .dr/ t .ds/
(5.15)
Œ0;1/
where the integral is a vague integral in the sense of Remark A.3. Theorem 5.19. The family . t / t >0 is a convolution semigroup of sub-probability measures on Œ0; 1/ whose corresponding Bernstein function is equal to f ı g. Moreover, Z (5.16) .1 e t / .dt/ .f ı g/./ D f .˛/ C ˇb C .0;1/
and the Lévy measure is given by the vague integral Z s .dt/ .ds/: .dt/ D b.dt/ C
(5.17)
.0;1/
Remark 5.20. (i) Once R formula (5.16) is established, it follows immediately that is a Lévy measure, i.e. .0;1/ .1 ^ t/ .dt/ < 1. (ii) The convolution semigroup . t / t >0 is called subordinate to . t / t >0 by . t / t >0 . If .S t / t>0 and .T t / t>0 are independent subordinators corresponding to . t / t >0 and . t / t >0 , respectively, then the subordinator corresponding to . t / t >0 is the process .T .S t // t >0 . This process, called a subordinate to T by the subordinator S , is a particular form of a stochastic time change: T .S t /.!/ D TS t .!/ .!/. We will extend the concept of subordination to strongly continuous semigroups on a Banach space in Section 12.2. Proof of Theorem 5.19. We check first that each t is a sub-probability measure. Indeed, Z Z t Œ0; 1/ D s Œ0; 1/ t .ds/ 6 t .ds/ 6 1: Œ0;1/
Œ0;1/
Let us compute the Laplace transform of the measure t : Z Z Z u L . t I / D e t .du/ D e Œ0;1/
Œ0;1/
Z D
Œ0;1/
s .du/
t .ds/
Œ0;1/
L .s I / t .ds/
Z D
u
e
sg./
t .ds/
Œ0;1/
D L t I g./ D e
tf .g.//
:
47
5 A probabilistic intermezzo
This proves also that L . t Cs I / D e De
.t Cs/f .g.// tf .g.//
sf .g.//
e
D L . t I /L .s I /; as well as vague continuity since t 7! L . t I / D e tf .g.// is continuous. In order to obtain formula (5.16), first note that e ˛s D s Œ0; 1/, and Z Z t .1 e / s .dt/ .ds/ .0;1/
.0;1/
Z
Z D
.1 Z e
˛s
L .s I / .ds/
.e
s˛
e
.0;1/
Z D
/ s .dt/ .ds/
.0;1/
.0;1/
D
e
t
sg./
/ .ds/
.0;1/
Z D
.1
sg./
e
Z .1
/ .ds/
Z D
e
˛s
/ .ds/
.0;1/
.0;1/
.1
sg./
e
/ .ds/
.f .˛/
a
b˛/:
.0;1/
Every function u 2 Cc .0; 1/ can be estimated by ju.t/j 6 c;u .1 e t /, t > 0, with a suitable constant c;u > 0. Therefore, the above calculation shows that the vague integral (5.17) exists and defines a measure on .0; 1/, cf. Remark A.3. Now we have Z .1 e tg./ / .dt/ f g./ D a C bg./ C .0;1/
Z
D a C b ˛ C ˇ C Z C
.1
e
t
.1
e
/ .dt/
.0;1/
Z /
.0;1/
.0;1/
s .dt/ .ds/ C f .˛/
Z D f .˛/ C ˇb C
t
.1
e
t
a
b˛
/ .dt/:
.0;1/
Comments 5.21. A good treatment of convolution semigroups and their potential theory is the monograph by Berg and Forst [29]; the classic exposition by Feller, [100], covers the material from a probabilistic angle and is still readable. Subordinators are treated in most books on Lévy processes, for example in Bertoin [36] and his St.-Flour course notes [38].
48
5 A probabilistic intermezzo
Infinitely divisible and self-decomposable functions can be found in many books on probability theory. The monograph by Steutel and van Harn [267, Sections I.5, V.2] is currently the most comprehensive study and has dedicated chapters for one-sided laws, but Gnedenko and Kolmogorov [108], Lukacs [206], Loève [203, vol. 1, Chapter VI], Petrov [232, pp. 82–87], [233, Chapters 3,4], Rossberg, Jesiak, Siegel [248, Sections 7, 11–13] and Sato [250, Chapter 3] contain most of the material mentioned in Remark 5.10. That all infinitely divisible functions in CM are of the form exp. BF/ was discovered by Schoenberg [255, Theorem 9, p. 835]. An alternative short proof is in Horn [142, Theorem 4.4]; note that one has to have Œ0; 1 as support of the measure d and not, as stated in [142], .0; 1/. Our presentation of the stable distributions is from Sato [250, Examples 24.12, 21.7], the representation of the Laplace exponents of self-decomposable distributions is from Steutel and van Harn [267, Theorem 2.11, p. 231]. The short proofs of Proposition 5.13 and Corollary 5.14 seem to be new. The proof of Proposition 5.15, which is due to Lévy [202, Section VII.55], is adapted from Sato [250, p. 95]. Self-decomposable distributions were characterized by P. Lévy as limit distributions of normed partial sums of sequences of independent random variables, see [201] and [202, pp. 192–193]; Lévy mentions that Khintchine drew his attention to this problem in a letter in 1936. The name self-decomposable appears for the first time in 1955 in the first edition of Loève’s book on probability theory [203], the notation L goes back to Khintchine [175], see the comment in Gnedenko and Kolmogorov [108, Section 29]. The best sources for potential theory of convolution semigroups are Berg and Forst [29, Chapter III] and the original papers by F. Hirsch from the early 1970s. A more probabilistic approach can be found in Bertoin [36, Chapter II, III]. A somewhat hard to read but otherwise most comprehensive treatment is the monograph by Dellacherie and Meyer [77, 78]. M. Itô [155, Section 2], see also [154], gives the following interesting characterization of potential measures and potentials: U is a potential measure on Œ0; 1/ if, and only if, R 1for all vaguely continuous convolution semigroups . t / t>0 of measures on, say Rd , the measure 0 t U.dt / is of the form R1 semigroup . t / t >0 of measures on Rd . Since 0 t dt for some other vaguely continuous convolution R1 d the potential measures on R are of the form 0 t dt, this means that P or the potential measures on Œ0; 1/ are characterized by the fact that they operate on the potentials in Rd . It is also shown in [155, pp. 118–119] that U is a potential measure on Œ0; 1/ if, and only if, it satisfies the domination principle, i.e. if for all continuous, positive and compactly supported v; w 2 CcC Œ0; 1/ U ? v 6 U ? w on supp v
implies
U ? v 6 U ? w on Œ0; 1/:
Subordination was introduced by Bochner in the short note [49], see also his monograph [50, Chapter 4.4]. A rigorous functional analytic and stochastic account is in the paper by Nelson [219].
Chapter 6
Complete Bernstein functions: representation
The class of complete Bernstein functions has been used throughout the literature in many branches of mathematics but under various names and for very different reasons, e.g. as Pick or Nevanlinna functions in (complex) interpolation theory, Löwner or operator monotone functions in functional analysis, or as class .S/ in the Russian literature on complex function theory in a half-plane. Many explicitly known Bernstein functions are actually complete Bernstein functions, which is partly due to the fact that the measure in the representation formula (3.2) for complete Bernstein functions has a nice density. We take this as our starting point and show that our definition coincides with other known approaches. Definition 6.1. A Bernstein function f is said to be a complete Bernstein function if its Lévy measure in (3.2) has a completely monotone density m.t/ with respect to Lebesgue measure, Z .1 e t / m.t/ dt: (6.1) f ./ D a C b C .0;1/
We will use CBF to denote the collection of all complete Bernstein functions. Denote by H" and H# the open upper and lower complex half-planes where Im z > 0 and Im z < 0, respectively. Theorem 6.2. Suppose that f is a non-negative function on .0; 1/. Then the following conditions are equivalent. (i) f 2 CBF. (ii) The function 7! f ./= is in S. (iii) There exists a Bernstein function g such that f ./ D 2 L .gI /;
> 0:
(iv) f has an analytic continuation to H" such that Im f .z/ > 0 for all z 2 H" and such that the limit f .0C/ D lim.0;1/3!0 f ./ exists and is real. (v) f has an analytic continuation to the cut complex plane C n . 1; 0 such that Im z Im f .z/ > 0 and such that the limit f .0C/ D lim.0;1/3!0 f ./ exists and is real.
50
6 Complete Bernstein functions: representation
(vi) f has an analytic continuation to H" which is given by Z z f .z/ D a C bz C .dt/ z C t .0;1/ where R a; b > 0 are non-negative constants and is a measure on .0; 1/ such that .0;1/ .1 C t/ 1 .dt/ < 1. Proof. (i),(ii) If m is completely monotone, we know from Theorem 1.4 that m D L for some measure on Œ0; 1/. By Fubini’s theorem Z Z Z t .1 e t /e ts dt .ds/ .1 e /m.t/ dt D Œ0;1/ .0;1/
.0;1/
Z D
Œ0;1/
Z D
Œ0;1/
1 s
1 Cs
s Cs
1
.ds/
.ds/:
The expression on the right-hand side converges R R if, and only if, ¹0º D 0, i.e. if is supported in .0; 1/, and if .0;1/ s 1 .ds/ C .1;1/ s 2 .ds/ < 1. This shows that a f ./ D CbC
Z .0;1/
1 s Cs
1
.ds/
is indeed a Stieltjes function. The converse direction follows easily by retracing the above steps. (ii))(iii) Note that h./ a has L .aI / D a as Laplace transform. Moreover, we have L .hI / D h.0C/ C L .h0 I /. Thus, a f ./ D b C CL2 s
1
.ds/I D b C L a C L s
1
.ds/ I
D L .gI /; where we set g 0 WD aCL .s 1 .ds// 2 CM so that g 2 BF, cf. the remark following Definition 3.1. R (iii))(i) If g.t/ D ˛ C ˇt C .0;1/ .1 e ts / .ds/, we find Z 1 Z ˇ ˛ C 2C e t .1 e ts / .ds/ dt 0 .0;1/ Z 1 1 2 D ˛ C ˇ C .ds/ Cs .0;1/
2 L .gI / D 2
6 Complete Bernstein functions: representation
51
1 .ds/ D ˛ C ˇ C s Cs .0;1/ Z 1 Z D ˛ C ˇ C .1 e t / e ts s 2 .ds/ dt Z
2
1 s
.0;1/
0
and (i) follows. R .dt/, the natural way to extend f (ii))(iv) Since f ./ D a C b C .0;1/ Ct is to replace by z 2 H" . If we write z D C i, then t z z zN C zt 2 C t C 2 Ci : D D 2 2 2 zCt jz C tj . C t/ C . C t/2 C 2 Moreover, for any fixed z D C i 2 H" we have 2 C t C 2 1 . C t/2 C 2 1Ct
and
t t . C t/2 C 2 1 C t2
(.t/ .t/ means that there exist two absolute constants c2 > c1 > 0 such that c1 .t/ 6 .t/ 6 c2 .t/) which entails that the integral Z .0;1/
z .dt/ D zCt
Z .0;1/
2 C t C 2 .dt/ C i . C t/2 C 2
Z .0;1/
t .dt/ . C t/2 C 2
converges locally uniformly and defines an analytic function on H" with positive imaginary part whenever D Im z > 0. All these remain true if we add a C bz. The above estimates and the integration properties of the measure also show that Z lim
H" 3z!0
.0;1/
z lim .dt/ D zCt .0;1/3!0
Z .0;1/
.dt/ D 0 Ct
so that the limit lim.0;1/[H" 3z!0 f .z/ D a exists and is real. (iv))(v) This is an easy consequence of the Schwarz reflection principle: since f j.0;1/ is real-valued, we may use f .z/ N WD f .z/, z 2 H" , to extend f across .0; 1/ to the lower half-plane. By the reflection principle this gives an analytic function on C n . 1; 0 D H" [ .0; 1/ [ H# . Since Im f .z/ D Im f .z/ < 0 for z 2 H" , we get Im f .z/ > 0 or Im f .z/ < 0 according to z 2 H" or z 2 H# , which can be expressed by Im z Im f .z/ > 0. Since limH" 3z!0 f .z/ exists and is real, the above construction automatically shows that the limit limCn. 1;03z!0 f .z/ exists. (v))(vi) Note that for p; q > 0 the function fp;q .z/ WD
p.f .z/ C iq/ p C .f .z/ C iq/
52
6 Complete Bernstein functions: representation
is analytic in H" . Write f .z/ D u.z/ C iv.z/ and observe that v.z/ > 0 on H" . Then fp;q .z/ D
p.u.z/ C p/u.z/ C p.v.z/ C q/2 i p 2 .v.z/ C q/ C : .u.z/ C p/2 C .v.z/ C q/2 .u.z/ C p/2 C .v.z/ C q/2
This shows that fp;q maps H" into itself. Moreover, on H" jfpq j D
pjf C iqj pjp C f C iqj C p 2 6 jp C .f C i q/j jp C .f C i q/j 6pC
p2 p2 : 6pC jIm .p C .f C i q//j q
Now set p D n and q D 1=n, n 2 N, and write fn .z/ WD fn;1=n .z/ D
f .z/ C 1C
1 n
i n
f .z/ C
i n2
:
Clearly, fn is analytic on H" , bounded 6 by 2n3 and limn!1 fn .z/ D f .z/. iR We want to apply Cauchy’s theorem. For this we fix z 2 H" and consider z + ih the following integration contour R ih (in counterclockwise orientation) consisting of a circular arc of radius R exθ θ tending from ! D to ! D . −R R The arc is closed by a straight line, parallel to the x-axis; the distance between this line and the x-axis is h D h.; R/. The parameters R and are chosen in such a way that z Cih lies inside R and zN Cih outside of R but not on the real axis. Using Cauchy’s formula we find Z 2 fn ./ fn00 .z C ih/ D d 2 i R . z ih/3 Z Z R cos 1 fn .t C ih/ 1 Re i! fn .Re i! / D dt C d!: i R cos .t z/3 .Re i! z ih/3 Since fn is bounded, the second integral converges to 0 as R ! 1. Therefore, Z 1 1 fn .t C ih/ fn00 .z C ih/ D dt: i 1 .t z/3 A similar calculation where we replace z C ih by zN C ih which is not surrounded by R shows Z 1 Z 1 1 fn .t C ih/ fn .t C ih/ 1 0N D dt D dt: i 1 .t zN /3 i 1 .t z/3
6 Complete Bernstein functions: representation
Adding these two equalities yields Z Z 2 1 Im fn .t C ih/ 2 fn00 .z C ih/ D dt D 1 .t z/3 Since
1 d2 2 dz 2 .s
C z/
fn .i C ih/
1
D .s C z/
1 1
Im fn . s C ih/ ds: .s C z/3
53
(6.2)
3
we find by integrating twice that for every > 0 Z i.1 / 1 1 fn .i C ih/ D Im fn . s C ih/ ds: 1 .i C s/.i C s/
Therefore, Im fn .i C ih/ Im fn .i C ih/ Z 1 1 .1 /.s 2 / D Im fn . s C ih/ ds 1 .1 C s 2 /. 2 C s 2 / Z 1 2 Z 1 s Im fn . s Cih/ Im fn . t Cih/ 1 1 ds D dt 2 2 2 2 1C.t/2 1 .1Cs /. Cs / 1 .1Ct / where we used the change of variables s D t in the last step. Using dominated convergence we get, as ! 0, Im fn .i C ih/ Im fn .ih/ Z Z 1 1 Im fn . s C ih/ 1 1 Im fn .ih/ ds dt D 1 1 C s2 1 1 C t2 Z 1 1 Im fn . s C ih/ ds Im fn .ih/: D 1 1 C s2 This and an application of Fatou’s lemma show that Im f .i C ih/ D lim Im fn .i C ih/ n!1 Z 1 1 Im fn . s C ih/ ds D lim n!1 1 C s2 1 Z 1 1 Im f . s C ih/ ds: > 1 1 C s2
(6.3)
We conclude that the family of measures ¹.1 C s 2 / 1 Im fn . s C ih/ dsºn2N is vaguely bounded, hence relatively compact in the vague topology of measures, cf. Theorem A.5; thus, every subsequence has a vaguely convergent subsequence. Note that limn!1 Im fn . s C ih/ D Im f . s C ih/ boundedly as is easily seen from n2 .Im f . s C ih/ C n 1 / .Re f . s C ih/ C n/2 C .Im f . s C ih/ C n 1 /2 Im f . s C ih/ C 1 6 .n 1 Re f . s C ih/ C 1/2
Im fn . s C ih/ D
6 CK .Im f . s C ih/ C 1/
54
6 Complete Bernstein functions: representation
as long as s is in a compact set K R and n is sufficiently large. This means that by dominated convergence Z 1 Z 1 Im fn . s C ih/ Im f . s C ih/ ds D ds lim .s/ .s/ 2 n!1 1Cs 1 C s2 1 1 for all 2 Cc .R/. Thus, the limiting measure is .1 C s 2 / 1 Im f . s C ih/ ds and we get from (6.2) Z 2 1 1 f 00 .z C ih/ D Im f . s C ih/ ds: 1 .z C s/3 From (6.3) we deduce with a similar argument that ¹Im f . s C ih/ dsºh>0 is a vaguely relatively compact family of measures. For some subsequence hk ! 0 we get 2 Im f . s C ihk / k!1 .ds/ ds ! 2 1Cs 1 C s2 R1 1 for a suitable limiting measure satisfying 1 1Cs 2 .ds/ 6 Im f .i/ < 1. We will see below in Corollary 6.3 that does actually not depend on the subsequence. Since limh!0 Im f . s C ih/ D 0 locally boundedly on the negative half-axis s < 0, the measure is supported in Œ0; 1/ and we get Z 1 00 f .z/ D .ds/: .z C s/3 Œ0;1/ Integrating twice, we find for w; z 2 H" , with a suitable constant b 2 C, Z z w 1 f .z/ f .w/ D b.z w/ C .ds/ 2 Œ0;1/ .z C s/.w C s/ and it is clear that this formula extends to all z; w 2 C n . 1; 0. In particular we get for z D > 0 and w D > 0 Z 1 f ./ f ./ D b. / C .ds/: 2 Œ0;1/ . C s/. C s/ If we set D 1 and let ! 1, we find that b > 0. By Fatou’s lemma and the finiteness of f .0C/ D lim!0 f ./ we conclude that Z .ds/ 1 : f ./ f .0C/ > 2 Œ0;1/ C s s This shows that ¹0º D 0 and we get Z f .z/ D a C bz C
.0;1/
z .ds/; zCs
where 0, b > 0 and .ds/ D 12 s 1 .ds/ is a measure on .0; 1/ such R a D f .0C/ > 1 that .0;1/ .1 C s/ .ds/ < 1. (vi))(ii) This is obvious if we take z D 2 .0; 1/.
6 Complete Bernstein functions: representation
55
Theorem 6.2 and its proof allow us to draw a few interesting conclusions. Corollary 6.3. The representation measure in Theorem 6.2(vi) is given by Z 1 1 .u; v D lim Im f . s C ih/ ds h!0C .u;v s Z 1 f . s C ih/ D lim Im ds s ih h!0C .u;v
(6.4)
which holds for all continuity points u; v of the distribution function t 7! . 1; t. Proof. The proof of Theorem 6.2 (v))(vi) shows that the limits appearing in (6.4) exist along some sequence .hk /k2N , 0 < hk ! 0. Since f is analytic in H" , the limit does not depend on the particular sequence and we conclude that (hence, ) is uniquely determined by f . Note that a D ¹0º. Moreover, a D f .0C/ D lim!0 f ./ and b D lim!1 f ./=. Remark 6.4. It follows from Theorem 6.2 and Corollary 6.3 that every function f 2 CBF can be uniquely represented in the following form Z (6.5) f ./ D a C b C .dt/; > 0; .0;1/ C t where a; b > 0 are non-negative constants and is a measure on .0; 1/ such that R 1 .dt/ < 1. (6.5) is called the Stieltjes representation of the function .1 .0;1/ C t/ f and the measure is called the Stieltjes measure of the function f . Corollary 6.5 (Angular limits; G. Julia et al.). Let f be (the analytic extension of) a complete Bernstein function. Then the limit f .Re i! / Db R!1 Re i! lim
exists uniformly for all ! 2 .;
/ and all fixed 2 .0; =2/.
Proof. Let z D Re i! with < ! < formula in Theorem 6.2(vi) we get
for some fixed 2 .0; =2/. From the
f .Re i! / a D CbC i! Re Re i!
Z .0;1/
.dt/ : Re i! C t
An elementary but somewhat tedious calculation shows that ˇ ˇ ˇ ˇ ˇ ˇ ˇ ˇ Re i! C t 1 RCt ˇ ˇDˇ ˇ ˇ Re i! C t ˇ ˇ R2 C 2Rt cos ! C t 2 ˇ 6 R2 2Rt cos C t 2 1 5 : 6 1 cos R C t
56
6 Complete Bernstein functions: representation
From dominated convergence we conclude f .Re i! / Db R!1 Re i! lim
uniformly for all ! 2 .; /. In fact, our consideration shows ˇ ˇ Z ˇ ˇ f .Re i! / 5 5 1 f .R/ ˇ6 a C ˇ 6 b .dt/ ˇ R ˇ Re i! 1 cos .0;1/ R C t 1 cos R which is valid for all ! 2 . C ;
b
/.
Corollary 6.6. Let f be (the analytic extension of) a complete Bernstein function. Then f .S / S with S D ¹z 2 C W 0 6 arg z 6 º; 2 .0; /: (6.6) Proof. This follows again from the formula in Theorem 6.2(vi). Indeed, if we add z D re i ; w D Re i 2 C, the argument of w C z lies between and ; a similar statement is true for integrals: Z arg f .t; z/ .dt/ 2 inf t arg f .t; z/; sup t arg f .t; z/ : Note that for all t > 0 re i z re i D i D 0 i 0 zCt re C t re
where 0 < 0 < :
z Thus, arg. zCt / 6 arg z and the same is true for f .z/ because of the formula in Theorem 6.2(vi).
An analytic function f that preserves the upper half-plane H" is often called a Pick function, a Nevanlinna function or a Nevanlinna–Pick function. Theorem 6.2 shows that complete Bernstein functions are exactly those Nevanlinna–Pick functions which are non-negative on the positive half-axis. A small change in the proof of Theorem 6.2 yields the canonical representation for (this particular class of) Nevanlinna–Pick functions. Theorem 6.7. The set CBF consists of all those Nevanlinna–Pick functions which are non-negative on .0; 1/. In particular, the following integral representations hold for all f 2 CBF and z 2 C n . 1; 0 Z zt 1 f .z/ D ˛ C ˇz C (6.7) .dt/ .0;1/ z C t Z t 1 D ˛ C ˇz C (6.8) .1 C t 2 / .dt/: 2 zCt .0;1/ 1 C t R R Here is a measure on .0; 1/ such that .0;1/ t 1 .dt/ C Œ1;1/ .dt/ < 1 and R ˛; ˇ > 0 are constants with ˛ > .0;1/ t 1 .dt/.
6 Complete Bernstein functions: representation
57
Proof. The equivalence of the two formulae (6.7) and (6.8) is obvious. Assume now that f is the function given by (6.7). Then f .z/
ˇz
˛
.0;1/
zt 1 .dt/ zCt
Z D Z D
.0;1/
Z D
.0;1/
Z z 1 1 t .dt/ .dt/ zCt t .0;1/ z C t Z z 1 1 tC .dt/ .dt/ zCt t .0;1/ t
Z .0;1/
1 .dt/ t
which becomes the formula in Theorem 6.2(vi) if we set .dt/ WD .t C t 1 / .dt/ D R t 2 C1 1 .dt/ and b WD ˇ. By assumption, a; b > 0 and .0;1/ t t .dt/, a WD ˛ Z Z Z Z t2 C 1 .dt/ .dt/ D C .dt/ < 1: .dt/ 6 2 t .0;1/ t.1 C t/ Œ1;1/ .0;1/ 1 C t .0;1/ The same calculation, run through backwards, shows that the formula in Theorem 6.2(vi) entails (6.7), and the proof is complete. Remark 6.8. (i) The (unique) representing measure from (6.7) of Theorem 6.7 is called the Pick measure or Nevanlinna measure or Nevanlinna–Pick measure. (ii) Just as in Corollary 6.3 we can calculate the coefficients ˛; ˇ and the representing measure appearing in (6.7) from f . Clearly, ˛ D Re f .i/; while
Z .u;v
ˇ D lim
1 h!0
.1 C t 2 / .dt / D lim
!1
f .i/ i
Z .u;v
Im f . s C ih/ ds
(6.9)
holds for all u < v which are continuity points of . To see this, recall from the proof of Theorem 6.7 that t .dt/ D .1 C t 2 / .dt/ where is the representing measure from the formula in Theorem 6.2(vi) and use Corollary 6.3. (iii) For further reference let us collect the relations between the various representing measures and densities appearing in Definition 6.1, Theorem 6.2 and Theorem 6.7: Z m.t/ D e ts s .ds/ D L s.ds/I t .0;1/
Z D .dt/ D
e .0;1/
t2
ts
.s 2 C 1/.ds/ D L .s 2 C 1/ .ds/I t ;
C1 .dt/: t
58
6 Complete Bernstein functions: representation
An analytic function ˆ on a domain is said to be of bounded type (or bounded character) if ˆ can be written as a quotient ˆ D G=H where G and H are bounded analytic functions in . If ˆ is of bounded type in the upper half-plane, it satisfies the canonical or Nevanlinna factorization, i.e. ˆ.z/ D cb.z/d.z/s.z/ where jcj D 1, b.z/ is a Blaschke product, see e.g. [208, Vol. 2, Section 36], Z 1 1 t d.z/ D exp q.t/ dt i R z C t 1 C t2 R with jq.t/j dt < 1, and Z 1 zt 1 !.dt/ g.z/ D 2 i R z C t R for some signed measure ! such that R .1 C t 2 / j!j.dt/ < 1, see e.g. Krylov [189, Theorem XX] and the comments below. Lemma 6.9. Let ˆ W H" ! H" be an analytic function such that Re ˆ > 0. Then ˆ is of bounded type. Proof. Note that j1 C ˆj > Re .1 C ˆ/ > 1. Therefore WD log j1 C ˆj is a nonnegative harmonic function on H" . Since H" is simply connected, is the real part of an analytic function h, i.e. Re h D . Define H WD e h and G WD ˆ e h . Clearly, G and H are analytic, jH j D je
h
jDe
Re h
De
61
and, since jˆj2 6 jˆj2 C 2Re ˆ C 1 D jˆ C 1j2 , log jGj D log jˆj
log jˆ C 1j 6 0I
thus, jGj 6 1. By definition ˆ D G=H , and the assertion follows. If f 2 CBF, ˆ.z/ WD if .z/ is analytic in H" and Re ˆ D Im f > 0. Lemma 6.9 tells us that if is of bounded type and has therefore a Nevanlinna factorization. This is the background for the next theorem. For CBF functions the factorization turns out to be rather easy and we can give a direct proof without resorting to the elaborate machinery of complex function theory in a half-plane. Theorem 6.10. For f 2 CBF, there exist a real number and a function on .0; 1/ taking values in Œ0; 1 such that Z 1 t 1 dt f ./ D exp C ; > 0: (6.10) .t/ 1 C t2 C t 0
6 Complete Bernstein functions: representation
59
Conversely, any function of the form (6.10) is in CBF. Thus there is a one-to-one correspondence between CBF and the set ° D . ; / W 2 R and W .0; 1/
measurable
± ! Œ0; 1 :
(6.11)
Proof. Assume first that f is given by (6.10). From the structure of the integral kernel it is clear that f extends to an analytic function for all z D C i 2 H" . Moreover,
1
.t/ dt 2 C 2 . C t/ 0 Z 1 dt 6 . C t/2 C 2 0 Z 1 6 dt D 2 C t2 1 Z
Im log f .z/ D
shows that f preserves the upper half-plane. Since f is positive on .0; 1/, f 2 CBF by Theorem 6.2. Conversely, assume that f 2 CBF. Using the principal branch of the logarithm we get g.z/ WD log f .z/ D log jf .z/j C i arg f .z/ and arg f .z/ 2 Œ0; /. This means that g maps z 2 H" to H" ; since g is clearly analytic in H" and real (but not necessarily positive) on .0; 1/, it is ‘almost’ a complete Bernstein function. Nevertheless, the argument used in the proof of Theorem 6.7 applies and shows that g.z/ D ˛ 0 C ˇ 0 z C
Z
t 1 C t2
1 zCt
.1 C t 2 / 0 .dt/
where ˛ 0 ; ˇ 0 2 R and 0 is on .0; 1/ such that 0 Œ1; R a measure R 1/ < 1. Note that 1 0 we no longer require that .0;1/ t .dt/ < 1 and that ˛ 0 > .0;1/ t 1 0 .dt/. This is only needed to ensure that g would be positive on .0; 1/. We will now determine the possible values of .˛ 0 ; ˇ 0 ; 0 /. Set WD ˛ 0 . Since f 2 CBF we know that f ./, > 0, grows at most linearly and g./ at most logarithmically as ! 1, i.e. ˇ 0 D 0. Using Remark 6.8(ii) we find that Z Z 1 2 0 .1 C t / .dt/ D lim Im g. s C ih/ ds h!0C .u;v .u;v Z 1 D lim arg f . s C ih/ ds 6 v C uC h!0C .u;v where we used that 0 is supported on .0; 1/ and that arg f . s C ih/ 2 Œ0; /. This means that .1 C t 2 / 0 .dt/ is absolutely continuous with respect to Lebesgue measure on .0; 1/ and that the density 0 .t/ takes almost surely values in Œ0; 1.
60
6 Complete Bernstein functions: representation
Remark 6.11. If f .0C/ > 0, we see that Z 1 Z 1 1 t 1 dt D .t/ dt > .t/ 2 C t 2/ 1 C t t t.1 0 0
1
R1 which is the same as to say that 0 .t/t 1 dt < 1. In this case we can rewrite the exponent in the representation (6.10) in the following form: Z 1 1 t .t/ dt
C 1 C t2 C t 0 Z 1 Z 1 1 t 1 1 dt C D C .t/ .t/ dt 1 C t2 t t Ct 0 0 Z 1 .t/ dtI DˇC Ct t 0 this is a function of the form RCCBF, i.e. an extended (complete) Bernstein function, see page 38. Therefore, we get the following multiplicative representation: ® ¯ CBF \ f W f .0C/ > 0 D e RCCBF D .0; 1/ e CBF : Comments 6.12. The notion of complete Bernstein function seems to appear first in the book by Prüss [240] in connection with Volterra-type integral equations. Prüss uses (iii) of Theorem 6.2 as definition of CBF: f ./ D 2 L .gI / where g is a Bernstein function. The specification complete derives from the fact that every Bernstein function can be written in the form 2 L .kI / where k is positive, nondecreasing and concave, cf. (3.4), whereas k 2 CM if f 2 CBF. Stieltjes functions and (complete) Bernstein functions were introduced into integral equations by G. E. H. Reuter [244] who found necessary and sufficient conditions so that certain Volterra integral equations have positive solutions; the starting point for Reuter’s investigations was a problem from probability theory. The equivalent integral representations for complete Bernstein functions from Theorems 6.2 and 6.7 have a long history. This is due to the fact that the class CBF has been used under different names and in different contexts. One of the earliest appearances of CBF is in the papers by Pick [236, 237] and, independently, R. Nevanlinna [221, 222] in connection with interpolation problems in C and the Stieltjes moment problem. Pick gives a characterization of all analytic functions in the unit disk or the upper halfplane which attain the values wj at the points jzj j 6 1 and Im zj > 0, j D 1; 2; : : : ; n, respectively; the class of functions on the half-plane that admit a unique solution of this interpolation problem satisfy (a discrete version of) the representation (6.7). Independently of Pick, Nevanlinna arrives in [221] at the same result for finitely and infinitely many interpolation pairs .zj ; wj /. In [222] Nevanlinna shows that Hamburger’s solution to the (extended) Stieltjes’ moment problem [115] can be equivalently stated in terms of analytic functions f in the upper complex half-plane with negative imaginary part. Nevanlinna proves the equivalence of conditions (iv) and (vi) of Theorem 6.2; note that he does not assume that f has a positive continuous extension to .0; 1/ (as we do). The main tool are methods from the theory of continued fractions and Schur’s algorithm [257]. Later, he gives in [223] a different proof for this representation. He solves the above described interpolation problem in the unit disk for infinitely many pairs .zj ; wj /. For the case where the zj are on the boundary of the disk or the upper half-plane, respectively, he employs earlier results of Julia [162] and Carathéodory [60] on non-tangential limits (also angular limits, Winkelderivierte in German). By the Cayley transform the open disk is mapped onto H" and the zj ’s are mapped into points j 2 R. Letting the j ’s collapse into a single point, the problem becomes the Stieltjes moment problem and one is back in the situation
6 Complete Bernstein functions: representation
61
of [222]. Note that this approach using non-tangential limits also yields (6.4) which is nowadays called Stieltjes inversion formula. It is interesting to note that Nevanlinna did not use Herglotz’ seminal paper [129] on the representation of analytic functions in the unit disk having positive real part. Using Herglotz’ result and the Cayley transform, Cauer [62] gives a short proof of the equivalence of Theorem 6.2(iv) and Theorem 6.7, and refers to [223] for Theorem 6.2(vi). Cauer’s approach is used by most modern presentations of the material, see e.g. Akhiezer [2, Chapter 3] or Akhiezer and Glazman [3, Vol. II, Sect. 59] for particularly nice proofs. Akhiezer [2] contains many interesting notes on the Russian school of complex function theory and operator theory. The paper [178] by Komatu gives a modern presentation of the material from the viewpoint of complex function theory in a half-plane. Hirsch [135, 136, 138] introduces complete Bernstein functions—in [138] they are referred to as family H —through a variant of (6.5). His intention was to find a cone of functions operating on Hunt kernels and more general abstract potentials [139]. Hirsch shows, among other things, the equivalence of (6.1) and (6.5) and that CBF are exactly those functions which operate on all densely defined, closed operators V on a Banach space such that . 1; 0/ is in the resolvent set and sup>0 k.id CV / 1 k < 1. This set includes the abstract potentials in the sense of Yosida [296, XIII.9], as well as all infinitesimal generators of strongly continuous contraction semigroups. The present rather complete form of Theorems 6.2 and 6.7 appeared in [251]—this proof is reproduced in [157, pp. 193–202]—see also [252] and [253] as well as the survey paper by Berg [25]. The elementary proof presented here seems to be new. The result contained in Corollary 6.5 is originally due to Julia [162], Wolff [291], Carathéodory [60] and one of the most elegant direct proofs is by Landau and Valiron [197]. Some of the above equivalences are part of the mathematical folklore; see e.g. Hirsch [136], Berg [22] or Nakamura [218] for corresponding remarks and statements. The Stieltjes-type inversion formulae appearing in Corollary 6.3 and Remark 6.8 are classical and can be found, e.g. in Akhiezer [2, p. 124], de Branges [76, Chapter 1.3] or Berg [23, 25]. The proof of the canonical or Nevanlinna factorization of bounded type in H" goes back to Krylov [189]. His paper is still highly readable and the formulation here is taken directly from [189, Theorem XX]. Other sources include Duren [88, Chapter 11.3], Hoffmann [141, pp. 132-3], de Branges [76, Chapter I.8] and Rosenblum and Rovnyak [247, Chapter 5]; in [247, Chapter 2] there is also a proof of Theorem 6.7 using methods from operator theory as well as a discussion of the Nevanlinna–Pick interpolation problem. The short proof of Theorem 6.10 is inspired by Krein and Nudelman [188, Appendix, Theorems A.3, A.8].
Chapter 7
Complete Bernstein functions: properties
The representation results of Chapter 6 enable us to give various structural results characterising complete Bernstein and Stieltjes functions. Our first aim is to make a connection between Stieltjes and complete Bernstein functions. For this the following result is useful. Proposition 7.1. f 2 CBF; f 6 0; if, and only if, the function f ? ./ WD =f ./ is in CBF. Proof. If f 2 CBF we may use the representation (6.5) and get Z a 1 f .z/ D CbC .dt/; z 2 C n . 1; 0: z z .0;1/ z C t Since Im z Im
1 Im z .Im z/2 D Im z D 60 2 zCt jz C tj jz C tj2
we see that f .z/=z maps H" into H# . As 1=z switches the upper and lower halfplanes, z=f .z/ D .z 1 f .z// 1 maps H" into itself. Further, =f ./ 2 .0; 1/ for > 0, and since a D lim!0C f ./, we have 8 <0; if a ¤ 0; lim D 1 1 R if a D 0: : !0C f ./ f ./ D .dt / 2 Œ0; 1/; lim!0C
bC
.0;1/
t
Theorem 6.2(iv) shows that =f ./ is in CBF. Conversely, if g./ D =f ./, 2 .0; 1/, is a complete Bernstein function, we can apply the just established result to this function and get CBF 3
D g./
f ./
D f ./:
Remark 7.2. We call f; f ? a conjugate pair of complete Bernstein functions. We can now prove a characterization of Stieltjes functions which was already announced in Chapter 2. Note that this theorem enables us to transfer all statements for complete Bernstein functions to Stieltjes functions. From a structural point of view one should compare this theorem with the definition of the cone P, Definition 5.16.
7 Complete Bernstein functions: properties
63
Theorem 7.3. A function f 6 0 is a complete Bernstein function if, and only if, 1=f 6 0 is a Stieltjes function. In other words ® ¯ ® ¯ CBF D f W 1=f 2 S and S D g W 1=g 2 CBF : ( CBF ; S refer to the not identically vanishing elements of CBF and S.) Proof. If f 2 CBF , Proposition 7.1 shows that 7! =f ./ is a complete Bernstein function, too. As such, z=f .z/, z 2 Cn. 1; 0, has a representation of the form (6.5), and dividing by z we see that 1=f .z/ is a Stieltjes function. Conversely, if 1=f 2 S , it is obvious from the definition of Stieltjes functions that z=f .z/ has a representation of the type (6.5) which means that z=f .z/ is a complete Bernstein function. By Proposition 7.1 this shows that f 2 CBF . The next Corollary is an immediate consequence of Theorem 7.3 combined with Theorem 6.2(iv), (v). Corollary 7.4. Let g be a positive function on .0; 1/. Then g is a Stieltjes function if, and only if, g.0C/ exists in Œ0; 1 and g extends analytically to C n . 1; 0 such that Im z Im g.z/ 6 0, i.e. g maps H" to H# and vice versa. The set S of Stieltjes functions plays pretty much the same role for CBF as do the completely monotone functions CM for the Bernstein functions BF. The following theorem is the CBF-analogue of Theorem 3.6 Theorem 7.5. Let f be a positive function on .0; 1/. Then the following assertions are equivalent. (i) f 2 CBF. (ii) g ı f 2 S for every g 2 S. (iii)
1 uCf
2 S for every u > 0.
Proof. (i))(ii) Assume that f 2 CBF and g 2 S. Clearly, g ı f ./ is positive for 2 .0; 1/ and by Theorem 6.2(iv) and Corollary 7.4 g ı f W H"
f
! H"
g
! H# :
Again by Corollary 7.4, g ı f 2 S. (ii))(iii) This follows from the fact that g./ WD gu ./ WD .u C / 1 , u > 0, is a Stieltjes function. (iii))(i) Note that for z 2 C n . 1; 0 Im z Im
1 Im f .z/ D Im z 60 u C f .z/ ju C f .z/j2
so that Im z Im f .z/ > 0. Since f j.0;1/ is positive we conclude from Theorem 6.2(v) that f 2 CBF.
64
7 Complete Bernstein functions: properties
Corollary 7.6. (i) The set CBF is a convex cone: if f1 ; f2 2 CBF, then sf1 C tf2 2 CBF for all s; t > 0. (ii) The set CBF is closed under pointwise limits: if .fn /n2N CBF and if the limit limn!1 fn ./ D f ./ exists for every > 0, then f 2 CBF and the Stieltjes measures n of fn converge vaguely on .0; 1/ to the Stieltjes measure of f . (iii) The set CBF is closed under composition: if f1 ; f2 2 CBF, then f1 ıf2 2 CBF. In particular, 7! f1 .c/ is in CBF for any c > 0. ! (iv) f 2 CBF is bounded on H if, and only if, in (6.5) b D 0 and .0; 1/ < 1. Proof. (i) This is obvious because of formula (6.5). (ii) Without loss of generality we may assume that f 6 0. Then fn ./ ! f ./ if, and only if, 1=fn ./ ! 1=f ./. By Theorem 7.3, 1=fn 2 S; since S is closed under pointwise limits, cf. Theorem 2.2, 1=f 2 S and, again by Theorem 7.3, f 2 CBF. Let n be the Lévy measure of fn , n 2 N, and the Lévy measure of f . It follows by Corollary 3.8 that limn!1 n D vaguely in .0; 1/. Let mn be the completely monotone density of n , n 2 N, and m the completely monotone density of f . Since mn and m are continuous and non-increasing, it is simple to show that limn!1 mn .t/ D m.t/ for all t > 0. By Remark 6.8, mn .t/ D L .sn .ds/I t/ and m.t/ D L .s.s/I dt/, and so limn!1 sn .ds/ D s.ds/ vaguely in Œ0; 1/, cf. the proof of Corollary 1.6. Therefore, limn!1 n D vaguely in .0; 1/. (iii) Let f1 ; f2 2 CBF. For any g 2 S we use Theorem 7.5 (i))(ii) to get g ı f1 2 S, and then g ı .f1 ı f2 / D .g ı f1 / ı f2 2 S. The converse direction (ii))(i) now shows that f1 ı f2 2 CBF. ! (iv) Note that for all z 2 H and t > 0 ˇ ˇ 2 2 ˇ z ˇ2 ˇ ˇ D .Re z/ C .Im z/ 6 1: ˇz C t ˇ .Re z C t/2 C .Im z/2 That b D 0 and .0; 1/ < 1 imply the boundedness of f j! is clear from the repreH sentation (6.5). Conversely, if f j! is bounded, b D 0 follows from Remark 3.3(iv), H and .0; 1/ < 1 follows from (6.5) and Fatou’s Lemma for z D ! 1, 2 Œ0; 1/. Here is the CBF-analogue of Proposition 3.10 which gives a one-to-one correspondence between bounded Stieltjes functions and bounded complete Bernstein functions. Proposition 7.7. If g 2 S is bounded, then g.0C/ g 2 CBF. Conversely, if f 2 CBF is bounded, there exist some constant c > 0 and some bounded g 2 S, lim!1 g./ D 0, such that f D c g. The constant can be chosen to be c D f .0C/ C g.0C/.
7 Complete Bernstein functions: properties
65
R Proof. Assume that g./ D a 1 C b C .0;1/ . C t/ 1 .dt/ is bounded. This R means that a D 0 and, by monotone convergence, .0;1/ t 1 .dt/ < 1. Again by R monotone convergence g.0C/ D b C .0;1/ t 1 .dt/ < 1. Hence,
Z f ./ WD g.0C/
g./ D
.0;1/
1 t
1 Ct
Z .dt/ D
.0;1/
.dt/ t C t
is a bounded complete Bernstein function, cf. Corollary 7.6(iv). R Conversely, if f 2 CBF is bounded, f ./ D a C .0;1/ . C t/ 1 .dt/ for , cf. Corollary 7.6. Thus f ./ D c g./ where g./ D Rsome bounded measure 1 .dt/ is a bounded Stieltjes function with lim t . C t/ !1 g./ D 0 and .0;1/ c D a C .0; 1/ D f .0C/ C g.0C/ > 0. Remark 7.8. Just as in the case of Bernstein functions, see Remark 3.11, we can understand the representation formula (6.5) as a particular case of the Kre˘ın–Milman or Choquet representation. The set ® ¯ f 2 CBF W f .1/ D 1 is a basis of the convex cone CBF, and its extremal points are given by e0 ./ D 1;
e t ./ D
.1 C t/ ; 0 < t < 1; Ct
and
e1 ./ D :
Their extremal property follows exactly as in Remark 2.4. Thus, 1;
;
; Ct
.0 < t < 1/
are typical functions in CBF. Using (6.5) with 1 t 1.1;1/ .t / dt
1
sin.˛/ t ˛
1 dt ,
1.0;1/ .t/
dt p 2 t
or
as the Stieltjes measures .dt/ we see that ˛ .0 < ˛ < 1/;
p
1 arctan p ;
log.1 C /
are also complete Bernstein functions. The closure assertion of Corollary 7.6 says, in particular, that on the set CBF the notions of pointwise convergence, locally uniform convergence, and even convergence in the space C 1 coincide. The next corollary comes in handy if we want to construct new complete Bernstein functions or Stieltjes functions from given functions in CBF or S. It also shows how these classes of functions operate on each other. To simplify the exposition we use shorthand notation of the type CBF ı S S to indicate that the composition of any f 2 CBF and g 2 S is an element of S.
66
7 Complete Bernstein functions: properties
Corollary 7.9.
(i) CBF ı S S;
(ii) S ı CBF S; (iii) CBF ı CBF CBF; (iv) S ı S CBF. Proof. All assertions follow in the same way: all composite functions are positive on the positive real line .0; 1/ and all that remains to be done is to track whether H" is mapped under the composite map to H" or H# . In the first case we get a complete Bernstein function, see Theorem 6.2(iv), otherwise we have a Stieltjes function, see Theorem 7.3. Corollary 7.9 contains many known characterizations of CBF and S. Several applications of Corollary 7.9 yield 7! f ./ 2 CBF
if, and only if,
7!
7! f ./ 2 S
if, and only if,
7!
1 f . 1 / 1 f . 1 /
2 CBFI
(7.1)
2 SI
(7.2)
just note that 7! 1= is a Stieltjes function. The same consideration applied to 7! =f ./, which is in CBF if, and only if, f 2 CBF, cf. Proposition 7.1, gives 1 7! f ./ 2 CBF if, and only if, 7! f 2 CBF: (7.3) Composing f 2 S with the complete Bernstein function 7! shows that f .f C 1/ orem 2.2; thus, 7! f ./ 2 S
1
1 D 1 C C 1
2 S. Letting ! 0 brings us back to f 2 S, cf. The-
if, and only if,
7!
f ./ 2 S for all > 0: f ./ C 1
(7.4)
Finally, if we compose f 2 S with 1= 2 S, we get 1=f 2 CBF and 1=.f .// 2 S by Theorem 6.2(ii). The same reasoning applied to the function 1=.f .// gives f 2 S, and we have shown 7! f ./ 2 S if, and only if,
7!
1 2 S: f ./
(7.5)
7 Complete Bernstein functions: properties
67
Proposition 7.10. CBF and S are both logarithmically convex, i.e. for all f1 ; f2 2 CBF and ˛ 2 .0; 1/ for all g1 ; g2 2 S and ˛ 2 .0; 1/
f1˛ f21 g1˛ g21
˛ ˛
2 CBF ;
2 S:
Proof. Since f 2 CBF exactly if 1=f 2 S, we only need to show the assertion for CBF. We give two arguments for this result: The first proof is based on Theorem 6.2(iv). Since f 2 CBF maps H" into itself, arg f .z/ 2 .0; / for all z 2 H" . Thus, arg f ˛ .z/ 2 .0; ˛/ and it is clear that 0 6 arg.f1˛ f21 ˛ / < ˛ C .1 ˛/ D for z 2 H" . This means that f1˛ f21 ˛ preserves the upper half-plane H" and is a complete Bernstein function. The second proof uses the representation of f1 ; f2 2 CBF from Theorem 6.10. If fj is represented by . j ; j / 2 , f1˛ f21 ˛ corresponds to the convex combination ˛. 1 ; 1 / C .1 ˛/. 2 ; 2 / which is again in . We will use the following shorthand: CBF˛ WD ¹f ˛ W f 2 CBFº and
S˛ WD ¹f ˛ W f 2 Sº
where CBF0 and S0 are, by definition, the non-negative constants. Moreover, note that CBF˙˛ D S˛ . Proposition 7.11. For ˛ 2 Œ 1; 1, the families CBF˛ and S˛ are convex cones. In fact, for ˛ 2 Œ0; 1, ® ¯ CBF˛ D f 2 CBF W 1 ˛ f ./ 2 CBF ; ® ¯ S˛ D f 2 S W ˛ 1 f ./ 2 S : Proof. The convexity follows immediately from the identities given in the second half of the proposition. Since S 1 D CBF and CBF 1 D S it is clearly enough to consider ˛ 2 Œ0; 1 and CBF. When ˛ D 1 the assertions are trivial. If ˛ D 0 and f 2 CBF, then f ./ can only be of class CBF if f is a positive constant. This follows from the fact that f ./ 2 CBF implies that =.f .// D 1=f ./ 2 CBF. On the other hand, 1=f 2 S and all functions CBF \ S must be both non-decreasing and non-increasing, hence constant. Fix ˛ 2 .0; 1/ and define ® ¯ Q˛ WD f 2 CBF W 1 ˛ f ./ 2 CBF : We prove that Q˛ D CBF˛ . If f 2 CBF˛ , then g D f 1=˛ 2 CBF. Thus by the logarithmic convexity of CBF, we have 1 ˛ f ./ D 1 ˛ g ˛ ./ 2 CBF, which implies that CBF˛ Q˛ .
68
7 Complete Bernstein functions: properties
Conversely, suppose f 2 Q˛ , that is, f 2 CBF and h./ WD 1 By Theorem 6.10, there exists a pair . ; / 2 such that Z 1 t 1 log f ./ D C .t/ dt; 1 C t2 C t 0
˛ f ./
2 CBF.
where is the set defined in (6.11). Since log h./ D .1 ˛/ log C log f ./ and Z 1 1 t dt; log D 1 C t2 C t 0 we have 1
Z log h./ D C 0
t 1 C t2
Since h 2 CBF, we have 0 6 .t/ C 1 f 1=˛ 2 CBF, that is, Q˛ CBF˛ .
1 Ct
.t/ C 1
˛ dt:
˛ 6 1, which implies 0 6 .t/ 6 ˛. Hence
Proposition 7.11 is very useful when it comes to compositions and products of complete Bernstein functions with fractional powers. The following corollary collects a few examples: Corollary 7.12. Let f; g 2 CBF. Then (i) .f ˛ ./ C g ˛ .//1=˛ 2 CBF for all ˛ 2 Œ 1; 1 n ¹0º; (ii) .f .˛ / C g.˛ //1=˛ 2 CBF for all ˛ 2 Œ 1; 1 n ¹0º; (iii) f .˛ / g.1
˛/
2 CBF for all ˛ 2 Œ0; 1.
Proof. Without loss of generality we can assume ˛ ¤ 0 throughout. (i) follows immediately from the fact that CBF˛ is a convex cone, cf. Proposition 7.11. (ii) can be rephrased as h.˛ /1=˛ 2 CBF where h WD f C g 2 CBF. Assume first that 0 < ˛ 6 1. Note that h 2 CBF implies = h./ 2 CBF. Therefore, ˛ = h.˛ / 2 CBF as well as 1 ˛ h.˛ / D =.˛ = h.˛ // 2 CBF. Since h.˛ / 2 CBF, we have h.˛ / 2 CBF˛ , and consequently h.˛ /1=˛ 2 CBF. If 1 6 ˛ < 0, set ˇ WD ˛ > 0. Since h.ˇ /1=ˇ is in CBF, (7.1) shows that also h.˛ /1=˛ D 1= h.1=ˇ /1=ˇ is a complete Bernstein function. To see (iii), observe that for f; g 2 CBF and ˛ 2 .0; 1/ part (ii) implies that f .˛ /1=˛ and g.1 ˛ /1=.1 ˛/ are in CBF; because of Proposition 7.10 we get f .˛ /g.1
˛
/ D f .˛ /1=˛
˛
g.1
˛ 1=.1 ˛/ 1 ˛ /
2 CBF:
The principle used in Corollary 7.12 to get new functions of type CBF from given ones can be generalized in the following way.
69
7 Complete Bernstein functions: properties
Proposition 7.13. Let f; g; h 2 CBF and f 6 0. Then (i) f ./ g. f ./ / 2 CBF; / 2 CBF. (ii) h.f .// g. f ./
Proof. (i) f; g 2 CBF implies that =f ./ and =g./ are in CBF; by Corollary 7.9(iii) the function f ./ g
f ./
D
g
f ./ f ./
is in CBF, and Proposition 7.1 shows f ./g.=f .// 2 CBF. (ii) Since f; g 2 CBF and f is non-zero, we know that =f ./, g.=f .// and, by (i), f ./g.=f .// are complete Bernstein functions. Thus, for every t > 0, f ./ C t f ./g
f ./
D
1 g
f ./
C
t f ./g
f ./
2S
or, equivalently, f ./ 1 g D f ./g 2 CBF: f ./ C t f ./ f ./ C t f ./ Since any h 2 CBF can be written as Z h./ D a C b C
.0;1/
.dt/; Ct
(7.6)
> 0;
we arrive at the desired conclusion by integrating (7.6) in t and adding the complete Bernstein function ag.=f .// C bf ./g.=f .//. Proposition 7.14. If f 2 CBF is non-constant, then for any 0 > 0, the functions 0 1 1¹D0 º ; 1¹¤0 º C 0 f ./ f .0 / f .0 / f ./ 0 f .0 / h./ D 1¹¤0 º C 0 f 0 .0 / C f .0 / 1¹D0 º ; 0 f ./ 0 f .0 / 1=2 f .0 / 1=2 k./ D 1¹¤0 º C 0 C 0 1¹D0 º ; f ./ f .0 / f .0 / 0 f 0 .0 / log f ./ 0 log f .0 / . / f 0 1¹D0 º `./ D exp 1¹¤0 º C f .0 / C e 0
g./ D
are in CBF.
70
7 Complete Bernstein functions: properties
Proof. Since f 2 CBF, f has a representation of the following form, cf. Theorem 6.7, Z t 1 f ./ D ˛ C ˇ C .dt/ .0;1/ C t for some ˛; ˇ > 0 and some measure on .0; 1/. For ¤ 0 we see f ./
f .0 / DˇC 0
Z .0;1/
1 1 C t2 .dt/: C t 0 C t
The right-hand side is defined for all > 0 and it is clearly an element of S. Moreover, if D 0 , the value f 0 .0 / extends the left-hand side continuously. This shows that the function g given in the statement of the proposition is defined for all > 0, it satisfies 1=g 2 S and, therefore, g 2 CBF. Further, h./ D
f ./
f .0 / C f .0 / D C f .0 / 2 CBF 0 g./
because of Proposition 7.1. Using the log-convexity of CBF we see 1=2 1=2 k./ D g./ h./ 2 CBF: For the function `./ we use the representation (6.10) for f to find log f ./ 0 log f .0 / 0 Z 1 t t D C .t/ dt 1 C t 2 . C t/.0 C t/ 0 Z 1 Z 1 0 t .t/ t D C dt C 2 /. C t/ .1 C t 1 C t2 0 0 0
log `./ D
Since 0 6 .t/ 6 1, we have 0 6 t.t/.0 C t/ CBF.
1
1 Ct
t.t/ dt: 0 C t
6 1 which shows that ` 2
Just as for Bernstein functions, cf. Proposition 3.4, we can characterize those complete Bernstein functions which have derivatives in S. R Proposition 7.15. Let h./ D a 1 CbC .0;1/ .Ct/ 1 .dt/ be a Stieltjes function R where a; b > 0 and with representing measure , i.e. .0;1/ .1 C t/ 1 .dt/ < 1. Then h has a primitive f which is in CBF if, and only if, a D 0 and if the representing measure satisfies Z Z 1 j log tj .dt/ C (7.7) .dt/ < 1: .0;1/ Œ1;1/ t
7 Complete Bernstein functions: properties
If the primitive f is a complete Bernstein function, it is given by Z f ./ D c C b C log 1 C .dt/ t .0;1/
71
(7.8)
where f .0C/ D c > 0 is some integration constant. Conversely, every function of the form (7.8) with the representing measure satisfying (7.7) is contained in CBF. Moreover, its derivative f 0 is in S. Proof. Let h be a Stieltjes function given by Z a 1 h./ D C b C .dt/: .0;1/ C t Using Fubini’s theorem we find for all > > 0 Z Z Z a 1 h.s/ ds D CbC .dt/ ds s .0;1/ s C t Z Z 1 ds .dt/ D a log C b. / C .0;1/ s C t Z t C1 .dt/: D a log C b. / C log .0;1/ t C1 Note that this expression has a finite limit as ! 0 if, and only if, a D 0 and if satisfies (7.7). Indeed, since log 1 C t log 1 C t lim lim D 1 and D ; t !1 log 1 C 1 t !0 log 1 C 1 t t the integral expression is finite, if and only if, Z 1 log 1 C .dt/ < 1: t .0;1/ Because of lim
t !0
log 1 C log 1t
1 t
D1
and
lim
t !1
log 1 C 1 t
1 t
D1
we get (7.7). If a D 0 and if the representing measure satisfies (7.7), the primitive f exists, and we have f .0C/ < 1. Therefore, f ./ is given by (7.8) and it is a complete Bernstein function. The latter follows from the fact that CBF is a convex cone which is closed under pointwise convergence. Conversely, if the primitive exists and if f 2 CBF, we know that f .0C/ < 1 and the above calculation shows that a D 0 and that the measure satisfies (7.7).
72
7 Complete Bernstein functions: properties
Comments 7.16. Proposition 7.1 appears in [218, 25] and, independently, in [253]. The second equality of Theorem 7.3 is already mentioned in [218] and it is implicitly contained in [135, 136]. Stability properties of CBF and S under particular compositions have been studied by Hirsch [135, 136], see also [23, 25]: the ‘if’ directions of (7.1)–(7.4) appear in [135], (7.5) is due to Reuter [244] and (7.2) and the Stieltjes version of (7.3) can be found in van Herk [284, Theorems 7.49, 7.50]. The general statement of Corollary 7.9 and the characterizations of CBF and S in terms of their stability properties, Theorem 7.5, seem to be new. The calculations for the examples in Remark 7.8 are the same as those of the corresponding Remark 2.4 for Stieltjes functions. An easier way to arrive there, without duplicating all calculations, would be to use the examples of Remark 2.4 and to observe that f 2 CBF if, and only if, f ./= 2 S, see Theorem 6.2(ii). The log-convexity of CBF and S, Proposition 7.10, was originally shown by Berg [22] using a rather complicated function-theoretic proof. Our first argument is from Nakamura [218] while the second is due to Berg, see [23]. The cones CBF˛ and S˛ were introduced by Nakamura [218] for ˛ ¤ 0, and Proposition 7.11 along p with Corollary 7.12 can be found there for positive ˛ > 0. Since lim˛!0 . 21 f ˛ C 21 g ˛ /1=˛ D fg (use, e.g. de l’Hospital’s rule), the limiting case of Corollary 7.12(i) contains yet another proof of the log-convexity of CBF. Part (ii) of Corollary 7.12 seems to be due to Ando [8]; for general j˛j 6 1 it appears, with a different proof using the mapping property of CBF, in [251, 252]. Proposition 7.13 is from Uchiyama [280, Lemma 2.1], but his proof of part (ii) has a gap. Proposition 7.14 is again from [218].
Chapter 8
Thorin–Bernstein functions
Proposition 7.15 contains a characterization of those complete Bernstein functions f whose derivative f 0 is a Stieltjes function. For probabilists this subclass of CBF is quite important, see Proposition 9.10 and Remark 9.17. We begin with a definition which reminds of the definition of complete Bernstein functions, Definition 6.1, based on the representation result for general Bernstein functions, cf. Theorem 3.2. Definition 8.1. A Bernstein function f is called a Thorin–Bernstein function if the Lévy measure from (3.2) has a density m.t/ such that t 7! t m.t/ is completely monotone, i.e. Z .1 e t / m.t/ dt; (8.1) f ./ D a C b C .0;1/
R where a; b > 0, .0;1/ .1 ^ t/ m.t/ dt < 1 and t 7! t m.t/ is completely monotone. We will use TBF to denote the family of all Thorin–Bernstein functions. t
Observe that the complete monotonicity of t 7! t m.t/ implies that also m.t/ D .t m.t// is completely monotone. Therefore, TBF CBF.
1
Theorem 8.2. For a function f W .0; 1/ ! .0; 1/ the following assertions are equivalent. (i) f 2 TBF. (ii) f 0 2 S and f .0C/ D lim!0C f ./ exists. (iii) f is of the form
f ./ D a C b C log 1 C .dt/ t .0;1/ Z
(8.2)
where a; b > 0 and with representing measure on .0; 1/ satisfying R R an unique 1 .dt/ < 1. j log t j .dt/ C t .0;1/ Œ1;1/ (iv) f 2 CBF and f 0 2 S. (v) f is of the form 1
Z f ./ D a C b C 0
w.t/ dt Ct t
(8.3)
where a; b > 0 are positive Rconstants and w W .0; 1/ ! Œ0; 1/ is a non1 decreasing function such that 0 .1 C t/ 1 t 1 w.t/ dt < 1. In order to assure uniqueness of w we can, and will, assume that w is left-continuous.
74
8 Thorin–Bernstein functions
Proof. (i))(ii) Let f 2 TBF. Then f .0C/ exists and is finite. Moreover, Z 1 f ./ D a C b C .1 e t / m.t/ dt; 0
where t m.t/ is completely monotone. Write t m.t/ D L .I t/ with a suitable measure . Differentiation gives Z 1 f 0 ./ D b C e t t m.t/ dt D b C L L .I t/ dtI ; 0
and by Theorem 2.2(i) we find f 0 2 S. (ii))(iii) By assumption, ˛ f ./ D C ˇ C 0
Z .0;1/
1 .dt/: Ct
Since the primitive f ./ exists with f .0C/ finite, we see that necessarily ˛ D 0 as well as Z f ./ D a C ˇ C log. C t/ log t .dt/ .0;1/
D a C ˇ C log 1 C .dt/: t .0;1/ Z
Since f is non-negative, the integration constant a has to be non-negative and if we set b D ˇ we have shown (8.2). Since f .1/ is finite, integrates R the function t 7! log.1 C t 1 / or equivalently, see the proof of Proposition 7.15, .0;1/ j log tj .dt/ C R 1 .dt/ < 1. The uniqueness of follows immediately from the uniqueŒ1;1/ t ness of the representing measure of Stieltjes functions, see the comment following Definition 2.1. (iii))(iv) This is the converse direction in Proposition 7.15. (iv))(v) By Proposition 7.15 every f 2 CBF with f 0 2 S is of the form (7.8). Using Fubini’s theorem we get Z Z 1 d ds .dt/ f ./ D f .0C/ C b C . 1/ log 1 C ds s .0;1/ t Z Z 1 1 D f .0C/ C b C ds .dt/ s Cs .0;1/ t Z 1 Z 1 D f .0C/ C b C .dt/ ds: C s s .0;s/ 0 This shows (8.3) with the left-continuous density w.t/ D .0; t/ and a D f .0C/; the integrability condition on w.t/ is a consequence of Fubini’s theorem and the fact that f .1/ < 1.
8 Thorin–Bernstein functions
75
(v))(i) We may use Fubini’s theorem to get Z 1 w.s/ f ./ D a C b C ds Cs s 0 Z 1 1 1 D a C b C w.s/ ds s Cs 0 Z 1Z 1 D a C b C .e st e .Cs/t / w.s/ dt ds 0 0 Z 1 Z 1 t ts D a C b C .1 e / e w.s/ ds dt: 0
0
Since w is non-decreasing, we have Z 1 Z 1 1 w.0C/ 1 w.s/ ds 6 ds < 1 1Cs s 1Cs s 0 0 which is only possible if w.0C/ D 0. Thus, w.s/ D .0; s/ for a suitable measure defined on .0; 1/, and thus Z 1 Z 1 Z e ts .du/ ds m.t/ WD e ts w.s/ ds D .0;s/ 1 ts
0
0
Z D
Z
e
.0;1/
1 D t
ds .du/
u
Z e
tu
.du/:
.0;1/
R Hence, t m.t/ D .0;1/ e tu .du/ is completely monotone, and (i) follows. A comparison with the formulae in the second half of the proof of Proposition 7.15 allows us, because of the uniqueness of the measure in (8.2), to identify .ds/ with .ds/. Remark 8.3. (i) (8.2) is called the Thorin representation of f 2 TBF and the (unique) representing measure appearing in (8.2) is called the Thorin measure of f . (ii) For further reference let us collect the relations between the various representing measures and densities from Definition 8.1 and Theorem 8.2: Z m.t/ D e ts w.s/ ds D L .wI t/I .0;1/
Z t m.t/ D
e .0;1/
w.t/ D .0; t/I .dt/ D
w.t/ dt: t
ts
Z dw.s/ D
e .0;1/
ts
.ds/ D L . I t/I
76
8 Thorin–Bernstein functions
(iii) The Thorin measure of f 2 TBF is the Stieltjes measure of the complete Bernstein function f 0 ./. This useful observation can be seen in the following way: Let f 2 TBF be given by Z f ./ D a C b C log 1 C .dt/: t .0;1/ Then f 0 2 S and 0
f ./ D b C
Z
1 .0;1/
1C
t
1 .dt/: t
Thus, f 0 ./ D b C
Z .0;1/
.dt/: Ct
This shows that whenever we have an explicit representation for f 2 TBF in terms of the Thorin measure, then we have an explicit representation of the complete Bernstein function f 0 ./ in terms of the Stieltjes measure. (iv) With formula (8.3) it is easy to find examples of complete Bernstein functions which do not have derivatives in S. For example, p Z 1 Z p 1 1 1 dt t f ./ WD arctan p D dt; p D 2 0 Ct t 0 Ct 2 t p R cf. Remark 7.8; but the density 12 t t 1.0;1/ .t / is clearly not of the form 1t .0;t / .ds/ which shows that f is of class CBF having a derivative which is not a Stieltjes function; in other words, f 2 CBF n TBF. The next two theorems describe the structure of the family TBF. Theorem 8.4. Let f 2 TBF. The following statements are equivalent. (i) g ı f 2 TBF for every g 2 TBF. (ii) f 0 =f 2 S. Proof. (ii))(i) Assume that f 2 TBF and f 0 =f 2 S. By Theorem 8.2, f 0 2 S. From 1=S D CBF we conclude that 1 f 0 ./ f ./Ct
D
f ./ t f ./ C t D 0 C D f 0 ./ f ./ f 0 ./
1 f 0 ./ f ./
C
t f 0 ./
is a complete Bernstein function. This means that f 0 ./=.f ./ C t/ is a Stieltjes function. For all g 2 TBF we know that g 0 2 S and Z 1 g 0 ./ D b C .dt/: .0;1/ C t
8 Thorin–Bernstein functions
77
Therefore .g ı f /0 ./ D g 0 f ./ f 0 ./ D bf 0 ./ C
Z .0;1/
f 0 ./ .dt/: f ./ C t
The integrand is a Stieltjes function, thus .g ı f /0 2 S. Since .g ı f /.0C/ < 1, Theorem 8.2 shows that g ı f 2 TBF. (i))(ii) Since g./ D log.1C=t/ 2 TBF for all t > 0, we see log.1Cf ./=t/ 2 TBF for all t > 0. This implies that f 0 ./ d f ./ D 7! log 1 C 2S d t t C f ./ for all t > 0. By letting t ! 0, we get that f 0 =f 2 S. Theorem 8.5. The set TBF is a convex cone which is closed under pointwise limits. Proof. That TBF is a convex cone follows immediately from the representation (8.1). Suppose that .fn /n2N is a sequence of functions in TBF such that limn!1 fn D f pointwise. It follows from Corollary 7.6(iii) that f 2 CBF and by Corollary 3.8 we find that limn!1 fn0 D f 0 . Since fn0 2 S, we get from Theorem 2.2 that f 0 2 S. Hence, f 2 TBF, cf. Theorem 8.2. Corollary 8.6. If .fn /n2N TBF with Thorin measures .n /n2N , and f D limn fn pointwise, then limn!1 n D vaguely in .0; 1/, where is the Thorin measure of f . Proof. This is proved similarly to the proof of Corollary 7.6(ii). The following assertion should be compared with Theorem 5.9. Proposition 8.7. Suppose that g W .0; 1/ ! .0; 1/. Then the following statements are equivalent. (i) g D e (ii)
f
where f 2 TBF.
.log g/0 2 S and g.0C/ 6 1.
Proof. Suppose that g D e f where f 2 TBF. Then g D e f where f 0 2 S, and since f D log g we get (ii). The converse assertion follows by retracing the steps backwards. Remark 8.8. Just as in the case of (complete) Bernstein functions, see Remarks 3.11 and 7.8, we can understand the representation formula (8.2) as a particular case of the Kre˘ın–Milman or Choquet representation.
78
8 Thorin–Bernstein functions
For this we rewrite (8.2) as log 1 C
Z f ./ D a C b C D
Œ0;1
log 1 C
.0;1/
log 1 C
Z
log 1 C
t 1 t
t 1 t
1 log 1 C .dt/ t
N .dt/
where N D aı0 C log.1 C t 1 / C bıR1 is a finite measure on Œ0; 1. Here we used, cf. the proof of Proposition 7.15, that .0;1/ log 1 C t 1 .dt/ < 1 and that lim
t !0
log 1 C log 1 C
t 1 t
D1
and
lim
t !1
log 1 C log 1 C
t 1 t
D :
The set ®
¯ f 2 TBF W f .1/ D 1
is a basis of the convex cone TBF, and its extremal points are given by log 1 C t e0 ./ D 1; e t ./ D ; 0 < t < 1; and e1 ./ D : log 1 C 1t Their extremal property follows exactly as in Remark 2.4. Thus, log 1 C t 1; ; ; .0 < t < 1/; log 1 C 1t are typical functions in TBF. Note that these are the logarithms of the Laplace transforms of the following (degenerate) Gamma distributions
0;0 ;
1;1 ;
and
.0 < t < 1/;
1= log.1C 1 /; t ;
As usual,
˛;ˇ .x/ D
t
ˇ˛ ˛ x .˛/
1
e
ˇx
;
respectively:
x > 0:
Comments 8.9. The class TBF appears for the first time in Thorin’s 1977 papers [274, 275] as the family of Laplace exponents of a class of probability distributions, the so-called generalized Gamma convolutions. This class of distributions will be discussed in the next chapter, Chapter 9. Nowadays the standard reference are the comprehensive lecture notes [54] by Bondesson and the monograph [267] by Steutel and van Harn. The exposition in Bondesson [54] focusses on probability distributions which are generalized Gamma convolutions, GGC for short. Bondesson calls, in honor of O. Thorin, the family of (sometimes: Laplace exponents of) distributions from GGC the Thorin class, T . It is easy to see that for f 2 T the reflected function 7! f . / is a Thorin–Bernstein function TBF in the sense of Definition 8.1. Taking this reflection into account, we find in [53, 54] the following further extensions of TBF: for 2 .0; 1/, Z 1 f 2 TBF if, and only if, f 0 ./ D b C .dt /
Œ0;1/ . C t /
8 Thorin–Bernstein functions
79
for some b > 0 and a suitable measure on Œ0; 1/. Thus, TBF1 D TBF and TBF2 D CBF. The integral appearing above is sometimes called generalized Stieltjes transform, see e.g. Hirschman and Widder [140]. The above mentioned reflection in the argument of the log-Laplace exponent makes Bonedesson sometimes difficult to read. The presentation in Steutel and van Harn [267] uses our convention but does not always contain (complete) proofs. Theorem 8.2 is, in less comprehensive form, essentially contained in [53], see also [54]. Note that Thorin [274] uses Theorem 8.2(iii) as definition of GGC or TBF, respectively. Since we want to emphasize the ‘(complete) Bernstein’ nature of TBF, we prefer (8.1) as the basic definition. Part (iv) of Theorem 8.2 is the main characterization theorem of GGC in [54]. It appears in [274] and in the present form in [53]; both references use the connection with complex analysis that complete Bernstein (respectively, Stieltjes) functions preserve (respectively, switch) the upper and lower half-planes, see Theorem 6.2. The stability result of Theorem 8.4 is the counterpart of [54, Theorem 3.3.1], the closure result Theorem 8.5 is due to Thorin [275]; among probabilists it is often referred to as Thorin’s continuity theorem. Theorem 9.12 was the starting point of Thorin’s investigations [274, 275]. Proposition 8.7 is due to Bondesson [53, Remark 3.2]. It provides, in particular, another proof for the fact that all probability distributions in GGC are infinitely divisible; this will again be proved in Proposition 9.10 of the next chapter. The interpretation of (8.2) in the context of Choquet theory seems to be new.
Chapter 9
A second probabilistic intermezzo
In Chapter 5 we discussed the relation between (extended) Bernstein functions BF and the infinitely divisible elements in CM, see Lemma 5.7 and Theorem 5.9. This allowed us to give a probabilistic characterization of the cone BF. A similar characterization is possible for complete Bernstein functions. To do this we use Lemma 5.7 as starting point. Definition 9.1. A measure on Œ0; 1/ belongs to the Bondesson class if L .I / D e
f ./
for some f 2 CBF. We write 2 BO. Note that 2 BO is a sub-probability measure: Œ0; 1/ D L .I 0C/ 6 1. A probabilistic characterization of the class BO will be given in Theorem 9.7 below. Let us first collect a few elementary properties of the Bondesson class BO. Lemma 9.2. (i) A sub-probability measure R on 1Œ0; 1/ is Rin BO if,2 and only if, there exist a measure on .0; 1/ with .0;1/ s .ds/ C .1;1/ s .ds/ < 1 and constants a; b > 0 such that Z 1 1 .ds/ : L .I / D exp a b (9.1) Cs .0;1/ s (ii) Every 2 BO is infinitely divisible. (iii) BO is closed under convolutions: if ; 2 BO, then ? 2 BO. (iv) BO is closed under vague convergence. Proof. (i) Because of Theorem 6.2, see also Remark 6.4, every f 2 CBF has a representation Z 1 1 f ./ D a C b C .ds/; Cs .0;1/ s with a; b and as claimed. (ii) Since CBF BF, Lemma 5.7 tells us that each 2 BO is infinitely divisible. (iii) Since CBF is a convex cone, this follows immediately from the convolution theorem for the Laplace transform: L . ? / D L L .
81
9 A second probabilistic intermezzo
(iv) Let .n /n2N BO be a sequence of sub-probability measures and denote by .fn /n2N CBF the complete Bernstein functions such that L .n I / D e fn ./ . If limn!1 n D vaguely, then limn!1 L .n I / D L .I / for every > 0, and the claim follows from the fact that CBF is closed under pointwise limits. Since CBF BF, Theorem 5.2 guarantees the existence of a unique semigroup of sub-probability measures . t / t >0 on Œ0; 1/ such that L . t I / D e tf ./ , t > 0; in particular, t 2 BO. Clearly, the converse is also true and we arrive at the analogue of Theorem 5.2. Theorem 9.3. Let . t / t >0 BO be a convolution semigroup of sub-probability measures on Œ0; 1/. Then there exists a unique f 2 CBF such that the Laplace transform of t is given by L t D e tf for all t > 0: (9.2) Conversely, given f 2 CBF, there exists a unique convolution semigroup of subprobability measures . t / t >0 BO such that (9.2) holds true. Note that the set e BF D ¹g W 9 f 2 BF; g D e f º is a relatively simple subset of CM: it consists of all infinitely divisible functions from CM \ ¹g W g.0C/ 6 1º, cf. Lemma 5.7. The structure of e CBF CM is more complicated. If we restrict our attention to g 2 CBF such that g.0C/ > 1, we find that f D log g D log .g 1/ C 1 2 CBF and e
f
D 1=g 2 S with 1=g.0C/ 6 1. This motivates the following definition.
Definition 9.4. A measure on Œ0; 1/ is a mixture of exponential distributions if L 2 S
and L .I 0C/ 6 1:
(9.3)
We write 2 ME. Note that 2 ME is a sub-probability measure: Œ0; 1/ D L .I 0C/ 6 1. The reason for the name mixture of exponential distributions is given in part (iii) of the following theorem. Theorem 9.5. Let be a measure on Œ0; 1/. Then the following conditions are equivalent. (i) 2 ME. (ii) There exist ˇ > 0 and a measurable function W .0; 1/ ! Œ0; 1 satisfying R1 1 0 .t/ t dt < 1, such that Z 1 1 1 .t/ dt : L .I / D exp ˇ (9.4) t Ct 0
82
9 A second probabilistic intermezzo
(iii) There exists a sub-probability measure on .0; 1 such that Z Œ0; t D .1 e ts / .ds/:
(9.5)
.0;1
Proof. (i))(ii) Since L .I / D g./ with g 2 S and g.0C/ 6 1 we know from Theorem 7.3 that f WD 1=g 2 CBF and f ./ > f .0C/ > 1. From the representation (6.10) of Theorem 6.10, we find that Z 1 1 t .t/ dt log f ./ D C 1 C t2 C t 0 for some 2 R and a measurable function W .0; 1/ ! Œ0; 1. Since 1 > f .0C/ > 1, we see that Z 1 1
C .t/ dt < 1 t.1 C t 2 / 0 R1 which entails that 0 .t/ t 1 dt < 1. Because of this integrability condition, we have Z 1 Z 1 1 1 1 t .t/ dt .t/ dt log f ./ D C 1 C t2 t Ct t 0 0 Z 1 1 1 DˇC .t/ dt: t Ct 0 Since f .0C/ > 1, we conclude that ˇ > 0. (ii))(iii) In view of Theorem 6.10 formula (9.4) means that L .I / is of the form 1=f where f 2 CBF and f .0C/ > 1; hence, h./ a Stieltjes R D L .I / is 1 function satisfying h.0C/ 6 1. But then h./ D b C .0;1/ . C s/ .ds/ and R b C .0;1/ s 1 .ds/ D h.0C/ 6 1. Define a sub-probability measure on .0; 1 by .ds/ D s 1 .ds/ on .0; 1/, and ¹1º D b. By Fubini’s theorem Z s L .I / D b C .ds/ .0;1/ C s Z 1 Z .Cs/t DbC e dt s.ds/ .0;1/
Z D
e Œ0;1/
Z D
t
e Œ0;1/
t
0
Z bı0 .dt/ C
e
Z se
Œ0;1/
Z bı0 .dt/ C
which is equivalent to saying that Œ0; t D
t
R
ts
.ds/ dt
.0;1/
se
ts
.ds/ dt
e
ts / .ds/.
.0;1/
.0;1 .1
9 A second probabilistic intermezzo
83
R (iii))(i) If Œ0; t D .0;1 .1 e ts / .ds/ we can perform the calculation of the previous step in reverse direction and arrive at Z s L .I / D b C .ds/: C s .0;1/ R R Set .ds/ D s.ds/. Since .0;1/ .1 C s/ 1 .ds/ D .0;1/ s.1 C s/ 1 .ds/ < 1, we see that L 2 S. Moreover, L .I 0C/ D b C .0; 1/ D .0; 1 6 1. Corollary 9.6. We have ME BO. Moreover, ME is closed under vague limits. Proof. Let 2 ME. By Theorem 9.5, the Laplace transform L is of the form e f where f 2 CBF BF. This shows that 2 BO. If .n /n2N ME converges vaguely to , we see that limn!1 L .n I / D L .I /. Since Stieltjes functions are closed under pointwise limits, cf. Theorem 2.2(iii), L 2 S is a Stieltjes function. Moreover, L .I 0C/ D lim!0C L .I / D lim!0C limn!1 L .n ; / 6 1. Thus, 2 ME. We are now ready for the probabilistic interpretation of the class BO. Theorem 9.7. BO is the vague closure of the set MEF WD ¹1 ? ? k W j 2 ME; j D 1; 2; : : : ; k; k 2 Nº, i.e. BO is the smallest class of sub-probability measures on Œ0; 1/ which contains ME and which is closed under convolutions and vague limits. Proof. We have already seen in Corollary 9.6 that ME BO. That BO is vaguely closed and stable under convolutions has been established in Lemma 9.2. It is therefore enough to show that the extremal elements of CBF, 7! 1;
7!
; Cs
s > 0;
7! ;
can be represented as pointwise limits of Laplace exponents of measures in MEF . For 7! 1 there is nothing to show. Note that Z 1 dt 1 D : lim rC1 r!1 log Ct t r r 1 2 N, we If we set r .t/ WD 1Œr;1/ .t/ and pick a sequence of r such that .log rC1 r / see that 7! is the limit of Laplace exponents of convolutions of measures from ME. Further, Z sC1=r r;s .t/ D lim r dt r!1 Cs C t t s 1=r
where r 2 N, t 1 r;s .t/ is a tent-function centered at s with basis Œs r 1 ; s C r 1 and height 1, i.e. r;s .t/ D rtŒ.t s C r 1 /C ^ .s C r 1 t/C . Therefore . C s/ 1 is the limit of Laplace exponents of convolutions of measures from ME. This proves that BO vague-closure.MEF /.
84
9 A second probabilistic intermezzo
Remark 9.8. The proof of Theorem 9.7 uses implicitly the representation of CBF in terms of its extremal points es ./ D .1 C s/=. C s/, 0 6 s 6 1, cf. Remark 7.8. It shows that we can approximate the corresponding representing measures ıs as vague limits of probability measures of the form c .1 C t/ 1 t 1 .t/ dt where W Œ0; 1/ ! Œ0; 1. Let us introduce a class of sub-probability measures which is related to the family TBF in the same way as BO is related to CBF, see Definition 9.1. Definition 9.9. A measure on Œ0; 1/ is a generalized Gamma convolution if L .I / D e
f ./
for some f 2 TBF. We write 2 GGC. Note that 2 GGC is a sub-probability measure: Œ0; 1/ D L .I 0C/ 6 1. A probabilistic characterization of the class GGC will be given below. Let us first collect a few elementary properties of this class. Proposition 9.10. (i) A sub-probabilityR measure is in GGC R if, and only if, there exist a measure on .0; 1/ with .0;1/ j log tj .dt/ C .1;1/ t 1 .dt/ < 1 and constants a; b > 0 such that Z L .I / D exp a b log 1 C .dt/ ; t .0;1/ R1 resp. a non-decreasing function w.t/ on .0; 1/ with 0 .1 C t/ 1 t 1 w.t/ dt < 1 such that Z w.t/ L .I / D exp a b dt : t .0;1/ C t (ii) GGC SD ID. (iii) GGC BO ID. (iv) GGC contains all Gamma distributions ˛;ˇ , ˛; ˇ > 0. (v) GGC is closed under convolutions: if ; 2 GGC, then ? 2 GGC. (vi) GGC is closed under vague convergence. Proof. Since TBF CBF BF, and since TBF is a convex cone which is closed under pointwise limits, (iii), (v) and (vi) follow as in Lemma 9.2. To see (ii), note that the Lévy measure of a Thorin–Bernstein function has a density m.t/ such that t m.t/ is completely monotone, cf. Definition 8.1; as such, t m.t/ is non-increasing and the assertion follows from the structure result for Laplace exponents of SD distributions, cf. Proposition 5.15. For (i) we have to use the representations (8.2) and (8.3) of
9 A second probabilistic intermezzo
85
Thorin–Bernstein functions. Property (iv) can be directly verified: suppose that ˛;ˇ is a Gamma distribution with parameters ˛; ˇ > 0, then L . ˛;ˇ I / D 1 C ˇ
˛
De
˛ log.1C ˇ /
De
f ./
:
The Thorin measure of f is equal to ˛ıˇ . Thus, GGC contains all Gamma distributions. Since TBF BF, Theorem 5.2 guarantees the existence of a unique semigroup of sub-probability measures . t / t >0 on Œ0; 1/ such that L . t I / D e tf ./ , t > 0; in particular, t 2 GGC. Clearly, the converse is also true and we arrive at the analogue of Theorem 5.2: Theorem 9.11. Let . t / t >0 GGC be a convolution semigroup of sub-probability measures on Œ0; 1/. Then there exists a unique f 2 TBF such that the Laplace transform of t is given by L t D e
tf
for all t > 0:
(9.6)
Conversely, given f 2 TBF, there exists a unique convolution semigroup of subprobability measures . t / t >0 GGC such that (9.6) holds true. We are now ready for the probabilistic interpretation of the class GGC. Theorem 9.12. GGC is the vague closure of the set ¹ ˛;ˇ W ˛; ˇ > 0ºF of all finite convolutions of Gamma distributions. In particular, GGC is the smallest class of subprobability measures on Œ0; 1/ which contains all Gamma distributions and which is closed under convolutions and vague limits. Proof. We have seen that ˛;ˇ 2 GGC in Proposition 9.10. Moreover, L . ˛;ˇ I / D e
˛ log.1C ˇ /
which shows that the extreme points e t ./ D log.1 C t /= log.1 C 1t /; 0 < t < 1, of TBF are the Laplace exponents of 1= log.1C 1 /; t , 0 < t < 1. t Since TBF are integral mixtures of its extreme points, cf. Remark 8.8, we conclude that GGC is the vague closure of finite convolutions of Gamma distributions. There seems to be no deeper relation between the classes ME and GGC. Indeed, the Laplace exponent of 2 ME is of the form Z 1 .t/ ˇC dt C t t 0
86
9 A second probabilistic intermezzo
with taking values in Œ0; 1; on the other hand, the Laplace exponent of a distribution in GGC looks like Z 1 w.t/ a C b C dt Ct t 0 where w is a non-decreasing function. The intersection GGC \ ME is characterized in Proposition 9.13(iii). We have seen in Proposition 9.10 that GGC distributions are self-decomposable, i.e. they satisfy (5.8). In fact, GGC contains all distributions that are S-self decomposable in the following sense: g D L , g.0C/ 6 1 and 7!
g./ g.c/
is a Stieltjes function for all c 2 .0; 1/:
(9.7)
Proposition 9.13. Let be a sub-probability measure and g D L . The condition (9.7) is equivalent to any of the following assertions. (i) 2 GGC with Laplace exponent f 2 TBF having no linear part, i.e. b D 0 in (8.3), and with a bounded density w.t/ 2 Œ0; 1. (ii) 2 GGC with Laplace exponent f 2 TBF having no linear part, i.e. b D 0 in (8.1) and such that t m.t/ D L .I t/ for some sub-probability measure on .0; 1/. (iii) 2 GGC \ ME. Proof. The equivalence of (i) and (ii) follows immediately from Remark 8.3(ii). Assume that (9.7) holds true; we want to show (i). Let us begin with the proof that 2 GGC. By (9.7), we get g 0 ./ g.c/ g./ 1 g./ D lim D lim 1 : c!1 .1 c!1 .1 g./ c/g.c/ c/ g.c/ Since g./=g.c/ is bounded by 1 and since it is a Stieltjes function, the expression inside the brackets is a complete Bernstein function by Proposition 7.7; dividing by transforms it into a Stieltjes function. Since limits of Stieltjes functions are again Stieltjes functions, cf. Theorem 2.2, we conclude that g 0 =g 2 S and so 2 GGC by Proposition 8.7. Consequently, L .I / D e f ./ where f 2 TBF; since f can be written as Z 1 w.t/ f ./ D a C b C dt; t C t 0 we see that g.c/ D exp b.1 g./
1
Z c/ C 0
w.t/ w.ct/ dt : t C t
87
9 A second probabilistic intermezzo
By assumption, 7! g./=g.c/ is a Stieltjes function so that, by Theorem 7.3, 7! g.c/=g./ is in CBF. In view of the uniqueness of the representation in Theorem 6.10 and Remark 6.11 this is only possible, if in the above representation b D 0 and 0 6 w.t/ w.ct/ 6 1 for all t > 0 and c 2 .0; 1/; letting c ! 0 proves w.t/ 2 Œ0;R 1. Here we used that w.0C/ D 0, which follows from the integrability 1 condition 0 .1 C t/ 1 t 1 w.t/ dt < 1. Conversely, assume that g D e f where f 2 TBF can be represented by (8.3) where b D 0 and w.t/ takes values in Œ0; 1 for all t > 0. For any 0 < c < 1 we find 1
Z f ./
f .c/ D 0 1
Z D 0
Z 1 w.t/ c w.t/ dt dt t C t t C c t 0 w.t/ w.ct/ dt: t C t
Since w.t/ is non-decreasing, we get w.t/ w is bounded by 1. Thus, g.c/ D exp f ./ g./
w.ct/ > 0 and w.t/ 1
Z
f .c/ D exp 0
w.ct/ 6 1 since
w.t/ w.ct/ dt ; t C t
and we conclude from Theorem 6.10 and Remark 6.11 that 7! g.c/=g./ is for all c 2 .0; 1/ a complete Bernstein function. Together with Theorem 7.3 this proves (9.7). Since S is closed under pointwise limits, cf. Theorem 2.2, and since g.0C/ > 0, (iii) follows from (9.7) if we let c ! 0. On the other hand, we infer (i) from (iii) by Theorem 6.10 and Remark 6.11. We will now discuss another class of probability measures on Œ0; 1/. This class is related to the exponential distributions in the same way as GGC is related to the Gamma distributions. Definition 9.14. Let CE be the smallest class of sub-probability measures on Œ0; 1/ which contains all exponential laws and which is closed under convolutions and weak limits. The class CE is called the class of convolutions of exponential distributions. It is straightforward to see that 2 CE if, and onlyP if, D ıc for some c > 0, or if there exist c > 0 and a sequence .bn /n>1 satisfying n bn 1 < 1 such that L .I / D e
c
Y 1C bn n
1
:
(9.8)
The sequence .bn /n>1 will be called the representing sequence of the measure .
88
9 A second probabilistic intermezzo
Corollary 9.15. (i) CE GGC. (ii) CE \ ME D Exp, where Exp denotes the family of all exponential distributions. Here the point mass at zero ı0 is interpreted as an exponential distribution with mean zero. Proof. (i) Let 2 CE. It follows from the representation (9.8) that L D e f with Z X f ./ D c C log 1 C log 1 C (9.9) D c C .dt/ bn t .0;1/ n P where D n ıbn . Thus f 2 TBF, and hence 2 GGC. (ii) Assume that 2 CE \ ME and ¤ ı0 . Let L D e f where f has the representation (9.9). Then the Stieltjes measure of f is given by .0; t/ #¹n W bn < tº dt D dt; t t cf. Remark 8.3(ii). On the other hand, comparing this representation with (9.4), it follows that t 7! .0; t/ is bounded by 1. Hence, D ıb for some b > 0. Again by comparing (9.4) and (9.9), it follows that c D 0 and ˇ D 0. Hence is an exponential distribution. .dt/ D
Suppose that 0 < b < a 6 1 and define a measure on .0; 1 by b b D 1 ıb C ı1 ; a a and a measure 2 ME by Z Œ0; t D
.1
e
ts
/ .ds/:
.0;1
Note that is the mixture of a point mass at 0 and the exponential distribution with parameter b. By integration it follows that 1 1C L .I / D 1 C : a b In the case when a D 1, is the exponential law with parameter b. Corollary 9.16. Let .an /n>1 and .bn /n>1 be two sequences of non-negative real numP bers such that 0 < bn < an 6 1 for all n > 1 and n bn 1 < 1. Then the function 1 Y ; > 0; g./ WD 1C 1C an bn n is well defined, strictly positive, and it is the Laplace transform of a probability measure from the Bondesson class. If all an D 1, then g is the Laplace transform of a probability measure from CE.
9 A second probabilistic intermezzo
89
Proof. By the assumptions on .an /n>1 and .bn /n>1 the product converges to a strictly positive function. Since the factors are Laplace transforms of probability measures in BO, the claim follows from Theorem 9.7. The case when an D 1 for all n 2 N follows from the definition of CE. Another way to prove the corollary is to notice that log 1 C 2 CBF 7! log 1 C an bn and to apply the closure property of CBF, Corollary 7.6. Remark 9.17. Let us briefly give an overview of all classes of distributions and their Laplace exponents we have encountered so far. The numbers n.m in the ‘references’ column of the table below refer to the corresponding statements in this tract. We use log-CM as a shorthand for logarithmically completely monotone (see Definition 5.8) and, analogously, log-S as a shorthand for logarithmically Stieltjes in the sense that the condition in Proposition 8.7(ii) holds. measure
Laplace transform
Laplace exponent
references
ID
log-CM
extended BF
5.6, 5.8, 5.9
ID, Œ0; 1/ 6 1
log-CM, f .0C/ 6 1
BF
5.7
SD
—
BF, .dt/ D m.t/ dt,
5.15
t m.t/ non-increasing BO
—
CBF
ME
S, f .0C/ 6 1
CBF, .dt/ D
9.1, 9.2 .t/ t
dt,
9.4, 9.5
0 6 .t/ 6 1 GGC CE Exp
log-S, f .0C/ 6 1 Q e c n 1 C bn 1 1 C b
TBF 1
TBF; D
8.7, 9.9, 9.10 P
TBF; D ıb
n ıbn
(9.8), 9.15 9.15
Overview of the classes of distributions, Laplace transforms and exponents We follow Bondesson [54] and use Venn diagrams to illustrate the relations among the classes of distributions and their Laplace exponents.
90
9 A second probabilistic intermezzo
BO ME Exp
GGC CE
ID
SD
Relations between various classes of distributions. . .
CBF t dσ dt ∈ [0, 1] τ =δb P τ = δbn
TBF
n
BF
t dµ dt
non-increasing
. . . and their Laplace exponents The non-inclusions shown in the above diagrams are easily verified by the following examples: SD 6 BO, in particular SD 6 ME. Consider the Lévy measure with density m.t/ D
1 1.0;1/ .t /; t
t > 0:
The corresponding Bernstein function is f ./ D RC log./ 1
D 0:5772 : : : is Euler’s constant and Ei./ D pv t 1 e
t
Ei./ where dt stands for
9 A second probabilistic intermezzo
91
the exponential integral. Clearly, t m.t/ is non-increasing, but m.t/ is not completely monotone. ME 6 SD, in particular BO 6 SD. This is shown by Entry 3 in the Tables 15.2. The corresponding Bernstein function is f ./ D 1 .1 C /˛ 1 , 0 < ˛ < 1. GGC 6 ME. This follows from Entry 1 in the Tables 15.2. The corresponding Bernstein function is f ./ D ˛ , 0 < ˛ < 1. ME 6 GGC. This follows from Entry 3 in the Tables 15.2. The corresponding Bernstein function is f ./ D 1 .1 C /˛ 1 , 0 < ˛ < 1. Comments 9.18. The class of Bondesson distributions, BO, appears first in Bondesson’s 1981 paper [53] under the name g.c.m.e.d. distributions. In his lecture notes [54] he also calls them class T2 distributions. The best source for the history is the following quote from Bondesson [54, p. 151] (with references pointing to our bibliography): The T2 [here: BO] distributions were introduced in [53] for the purpose of finding a class of ID densities containing the MED’s [here: ME] as well as the B-densities [B denotes the hyperbolically completely monotone functions]. The attempt was not successful and I [i.e.: L. Bondesson] have often considered the class as a failure. Others have been much more interested in it and my name was even attached to it by Kent [173]. Unfortunately, some people have also called it B, e.g. Küchler & Lauritzen [194]. Earlier, Ito & McKean [152, pp. 214–217] encountered the class in connection with first passage times for diffusion processes [see Chapter 14]. Thorin introduced the notion of generalized Gamma convolutions in his two 1977 papers [274, 275] in order to show the infinite divisibility of certain probability distributions. Subsequently, a large number of papers appeared on the subject, many of them in the Scandinavian Actuarial Journal. Nowadays the standard texts in the field are the survey paper [53] and the comprehensive lecture notes [54] by Bondesson. Chapter VI of the monograph [267] by Steutel and van Harn contains a digest of this material. Most of the results of this section are already in the original papers by Thorin [274, 275] and Bondesson [53]. New is the presentation, which emphasizes the analogy with the material of Chapter 5, in particular with infinite divisibility and self-decomposability. Theorem 9.3 is from [53], Theorem 9.5 and its Corollary 9.6 are due to Steutel [266]. Our proof of Theorem 9.7 seems to be new. Alternatively, it is also possible to construct 2 vague-closure.MEF / such that L .I / D exp =. C t / resp. L .I / D exp. b/. Typically, such distributions are vague limits of convolutions of elementary measures of the form .t C / 1 ı t C t .t C / 1 ı1 . This is the usual way to prove Theorem 9.7, see e.g. Steutel and van Harn [267, Chapter VI.3] and Bondesson [54, p. 141]. The first part of Proposition 9.10 appears as Theorem 5.2 in [53], while all other assertions seem to be general knowledge. Theorems 9.11 and 9.12 are due to Thorin [274, 275], while Proposition 9.13 and the notion of S-self decomposability seem to be new. Probabilistically, (9.7) can be interpreted in the following way: (the distribution of) a random variable X is S-self decomposable if, and only if, X has a GGC distribution and if for every c 2 .0; 1/ there is a further random variable X .c/ with distribution in GGC such that X D cX C X .c/ . The class of convolutions of exponential distributions, CE, is introduced by Yamazato in [293], see also [294], in the context of first passage distributions. The notion itself appears in the same context much earlier, see Keilson [169] and Kent [171, 172]. Corollary 9.16 is taken from Kent [171, 172]; he refers to this class of distributions as infinite convolutions of elementary MEDs, i.e. mixtures of exponential distributions. The diagrams appearing in Remark 9.17 owe much to the presentation in Bondesson [54, p. 4].
Chapter 10
Special Bernstein functions and potentials
In the first section of this chapter we will focus our attention on a less known family of Bernstein functions, the special Bernstein functions. This family, denoted by SBF, contains CBF and inherits some of its good properties. The main interest in special Bernstein functions lies in the fact that the potential measure, restricted to .0; 1/, of the convolution semigroup corresponding to a special Bernstein function admits a non-increasing density. On the other hand, a non-increasing function on .0; 1/ need not be a potential density of any convolution semigroup. The best known sufficient condition for this to be true is that the function is non-increasing and log-convex. The Laplace transforms of such functions form the so-called Hirsch class of functions which is between the families S and CM. The Hirsch class is studied in the second part of this chapter.
10.1
Special Bernstein functions
It was shown in Proposition 7.1 that f 6 0 belongs to CBF if, and only if, the function 7! =f ./ belongs to CBF. Generalizing this property leads to the larger class of special Bernstein functions which enjoy certain desirable properties. On the other hand, the class itself does not have good structural properties. Definition 10.1. A function f 2 BF is said to be a special Bernstein function if the function f ? ./ WD =f ./ is again a Bernstein function, i.e. f ? 2 BF. We will use SBF to denote the collection of all special Bernstein functions. A subordinator S whose Laplace exponent f belongs to SBF will be called a special subordinator. Note that if f 2 SBF, then also f ? 2 SBF, where f ? ./ WD =f ./. We call f and f ? a conjugate pair of special Bernstein functions. It is clear from Proposition 7.1 that CBF SBF. We will show later that CBF ¤ SBF ¤ BF, cf. Propositions 10.16, 10.17 and Example 10.18. Remark 10.2. Suppose that f 2 BF. Then =f ./ 2 BF if, and only if, f ./= 2 P. Hence f 2 SBF if, and only if, f 2 BF and f ./= 2 P.
93
10.1 Special Bernstein functions
Let Z f ./ D a C b C ?
?
.1
e
t
/ .dt/;
(10.1)
e
t
(10.2)
.0;1/
?
f ./ D a C b C
Z .1
/ ? .dt/
.0;1/
be representations of f and its conjugate f ? . Then, using the convention 8 <0; a > 0; D a? D lim f ? ./ D lim : R 1 !0 !0 f ./ ; a D 0; bC .0;1/ t .dt/ 8 <0; b > 0; f ? ./ 1 D b ? D lim D lim 1 : !1 !1 f ./ ; b D 0:
1 1
D 0, (10.3)
(10.4)
aC.0;1/
The following theorem gives a characterization of a special subordinator in terms of its potential measure. Roughly speaking, it says that a subordinator is special if, and only if, its potential measure restricted to .0; 1/ has a non-increasing density. Theorem 10.3. Let S be a subordinator with potential measure U . Then S is special if, and only if, U.dt/ D cı0 .dt/ C u.t/ dt (10.5) for R 1 some c > 0 and some non-increasing function u W .0; 1/ ! .0; 1/ satisfying 0 u.t/ dt < 1. Remark 10.4. (i) In general, theRmeasure U given by (10.5)—with c > 0 and a non1 increasing function u satisfying 0 u.t/ dt < 1—need not be the potential measure of any subordinator. For example, if U.dt/ D u.t/ dt with u.t/ D 1 ^ e 1 t , then L .U I / D
1C e : .1 C /
If U were the potential measure of a subordinator, then f ./ WD 1=L .U I / would be a Bernstein function, see (5.14). A direct calculation shows that, for example, f 00 .1/ > 0, hence f 62 BF. (ii) Let f 2 BF be the Laplace exponent of the subordinator S. Theorem 10.3 can be equivalently stated in the following way: f 2 SBF if, and only if, Z 1 1 DcC e t u.t/ dt (10.6) f ./ 0 for R 1 some c > 0 and some non-increasing function u W .0; 1/ ! .0; 1/ satisfying 0 u.t/ dt < 1.
94
10 Special Bernstein functions and potentials
Proof of Theorem 10.3. Suppose that S is a special subordinator, and let f be its Laplace exponent. Then f and its conjugate f ? have representations (10.1) and (10.2) where the coefficients a? and b ? are given by (10.3) and (10.4). Define u.t/ WD a? C ? .t; 1/;
t > 0;
(10.7)
and note that L .U I / D
1 f ? ./ a? D D C b? C f ./ Z 1 ? Db C e
1
Z
e
t
? .t; 1/ dt
0 t
u.t/ dt:
0
This shows that U.dt/ D bR? ı0 .dt/Cu.t/ dt, with u given by (10.7). It is clear that u 1 is non-increasing and that 0 u.t/ dt < 1. Conversely, suppose that (10.5) R 1 holds with a density u W .0; 1/ ! .0; 1/ which is non-increasing and satisfies 0 u.t/ dt < 1. Then 1 D L .U I / D c C f ./
1
Z
e
t
u.t/ dt:
0
Let be the measure on .0; 1/ defined by .t; 1/ D u.t/ lim t !1 u.t/. Then Z
Z .0;1
s .ds/ D
s
Z .0;1
u.1/, where u.1/ D
Z 1Z dt .ds/ D
.ds/ dt
0
.t;1
0 1
Z D
u.t/
u.1/ dt < 1
0
by the assumption on u. Hence, Fubini’s theorem that Z 1 D c C e f ./ 0
R
.0;1/ .1
^ s/ .ds/ < 1. It follows from (10.6) by 1
Z
t
u.1/ dt C
Z
1
e
t
u.t/
u.1/ dt
0
D c C u.1/ C
e
t
.t; 1/ dt
0
Z D c C u.1/ C
.1
e
t
/ .ds/:
(10.8)
.0;1/
Therefore, =f ./ is a Bernstein function and S is a special subordinator. Remark 10.5. In case c D 0, we will call u the potential density of the subordinator S or of the Laplace exponent f .
10.1 Special Bernstein functions
95
The following remark provides yet another characterization of complete Bernstein functions, this time in terms of the corresponding potential measures. Remark 10.6. Let S be a subordinator with Laplace exponent f and potential measure U . Then f is a complete Bernstein function if, and only if, U restricted to .0; 1/ has a completely monotone density u. This follows immediately from Theorem 7.3 and Theorem 2.2. If we compare the expressions (10.2) and (10.8) for (10.3) and (10.4), we get immediately 8 <0; c D b? D 1 : ; aC.0;1/ 8 <0; u.1/ D a? D : R 1 ; bC t .dt/ .0;1/
=f ./, and use formulae
b > 0; b D 0; a > 0; a D 0;
u.t/ D a? C ? .t; 1/:
(10.9)
In particular, it cannot happen that both a and a? are positive, or that both b and b ? are positive. Moreover, Rit is clear from the definition of a? and b ? that a? > 0 if, and only if, a D 0 and .0;1/ t .dt/ < 1, and b ? > 0 if, and only if, b D 0 and .0; 1/ < 1. The following two corollaries follow immediately, if we combine Theorem 10.3 and Remark 3.3(v) with the formulae for a? ; b ? and (10.9). Corollary 10.7. Suppose that S D .S t / t >0 is a subordinator whose Laplace exponent Z .1 e t / .dt/ f ./ D a C b C .0;1/
is a special Bernstein function with b > 0 or .0; 1/ D 1. Then the potential measure U of S has a non-increasing density u satisfying Z lim tu.t/ D 0 and
t !0
lim
t !0 0
t
s du.s/ D 0:
(10.10)
Corollary 10.8. Suppose that S D .S t / t >0 is a special subordinator with the Laplace exponent given by Z f ./ D a C
.1 .0;1/
e
t
/ .dt/
96
10 Special Bernstein functions and potentials
where satisfies .0; 1/ D 1. Then f ./ WD D a? C f ./ ?
Z .1
e
t
/ ? .dt/
(10.11)
.0;1/
where the Lévy measure ? satisfies ? .0; 1/ D 1. Let T be a subordinator with Laplace exponent f ? . If u and v denote the potential densities of S and T , respectively, then v.t/ D a C .t; 1/:
(10.12)
In particular, a D v.1/ and a? D u.1/. Assume that f is a special Bernstein function of the form (10.1) where b > 0 or .0; 1/ D 1. Let S be a subordinator with Laplace exponent f , and let U denote its potential measure. By Corollary 10.7, U has a non-increasing density u W .0; 1/ ! .0; 1/. Let T be a subordinator with Laplace exponent f ? ./ D =f ./ and let V denote its potential measure. Then V .dt/ D bı0 .dt/ C v.t/ dt where v W .0; 1/ ! .0; 1/ is a non-increasing function. If b > 0, the potential measure V has an atom at zero, and hence the subordinator T is a compound Poisson process. If b D 0, we require that .0; 1/ D 1, and then, by Corollary 10.8, f ? has the same structure as f , namely b ? D 0 and ? .0; 1/ D 1. In this case, the subordinators S and T play symmetric roles. The defining property of special Bernstein functions says that the identity function is factorized into the product of two Bernstein functions. The following theorem is the counterpart of this property in terms of potential densities. Theorem 10.9. Let f be a special Bernstein function with representation (10.1) satisfying b > 0 or .0; 1/ D 1. Then Z t Z t b u.t/ C u.s/v.t s/ ds D b u.t/ C v.s/u.t s/ ds D 1; t > 0: (10.13) 0
0
Proof. Since for all > 0 we have 1 D L .uI /; f ./
f ./ D b C L .vI /;
we get after multiplying 1 D bL .uI / C L .uI /L .vI / D bL .uI / C L .u ? vI /: By Laplace inversion we see t
Z 1 D b u.t/ C
u.s/v.t 0
s/ ds;
t > 0:
10.1 Special Bernstein functions
97
Our next goal is to describe a sufficient condition on the Lévy measure of the subordinator which guarantees that the subordinator is special. Since logarithmic convexity will play a major role, we recall the definition. Definition 10.10. (i) A function f W .0; 1/ ! .0; 1/ is said to be logarithmically convex (or log-convex) if log f is convex. (ii) A sequence .an /n>0 of non-negative real numbers is logarithmically convex (or log-convex) if an2 6 an 1 anC1 for all n > 1. Let f be a Bernstein function with the representation (10.1). It will be convenient to extend the measure onto .0; 1 by defining ¹1º D a. Let .x/ N WD .x; 1, x > 0, be the tail of . Then one can write, as in Remark 3.3(ii), Z 1 f ./ D b C e t .t/ N dt: (10.14) 0
Theorem 10.11. Suppose that f is given by (10.14) and that x 7! .x/ N is log-convex on .0; 1/. (i) If b > 0 or .0; 1/ D 1, then the potential measure U has a non-increasing density u. (ii) If b D 0 and .0; 1/ < 1, then the restriction U j.0;1/ has a non-increasing density u. In both cases, f 2 SBF. Before we give the proof of the theorem we note some immediate consequences. Corollary 10.12. R 1 Suppose that u W .0; 1/ ! .0; 1/ is non-increasing, log-convex and satisfies 0 u.t/ dt < 1, and let c > 0. Then the measure U defined by U.dt/ D cı0 .dt/ C u.t/ dt is the potential measure of a special subordinator S D .S t / t>0 . Proof. Set a? WD u.C1/ and define Ra measure ? on .0; 1/ by ? .t; 1/ WD u.t/ a? . Then ? is a Lévy measure, i.e. .1 ^ t/ ? .dt/ < 1, and the tail ? .t; 1 D u.t / is log-convex. R Define f ? ./ WD a? C b ? C .0;1/ .1 e t / ? .dt/, where b ? D c. By Theorem 10.11, f ? is a special Bernstein function. Let f ./ WD =f ? ./ with corresponding special subordinator S D .S t / t >0 . It follows from Theorem 10.3 and (10.9) that the potential measure of S is given by b ? ı0 .dt/ C a? C ? .t; 1/ dt D cı0 .dt/ C u.t/ dt D U.dt/: Hence, U is the potential measure of the special subordinator S .
98
10 Special Bernstein functions and potentials
Remark 10.13. As a consequence of the above corollary, we can conclude that L U 2 P. In this form, Corollary 10.12 is due to [137]. See also [29, Corollary 14.9], and [154, 155]. Corollary 10.12 will be strengthened in the next section, see Theorem 10.23. In order to prove Theorem 10.11 we need two preliminary lemmas. Lemma 10.14. Let .vn /n>0 be a sequence satisfying v0 D 1 and 0 < vn 6 1, n > 1. Assume that .vn /n>0 is a log-convex sequence. Then there exists a non-increasing sequence .rn /n>0 such that rn > 0 for all n > 0, and 1D
n X
rj vn
for all n > 0:
j
(10.15)
j D0
Proof. Note that the inequality vn2 6 vn 1 vnC1 is equivalent to vn =vn Therefore, the sequence .vn =vn 1 /n>1 is non-decreasing. Define f1 WD v1 and recursively fn WD vn
n 1 X
fj vn
j;
n D 2; 3; : : :
1
6 vnC1 =vn .
(10.16)
j D1
We claim that fn > 0 for all n > 1. This is clear for f1 . Assume that fk > 0 for 1 6 k 6 n. Then n X vnC1 j vnC1 vn fj vn vn vn j j D1 0 1 n X vnC1 @ > vn fj vn j A vn
fnC1 D
j
j D1
D 0; where the inequality follows since .vn =vn 1 /n>1 is non-decreasing; the last equality comes from (10.16) and the fact that v0 D 1. P1 P n n Let V .z/ WD 1 nD1 fn z . Since .vn /n>0 is a bounded nD0 vn z and F .z/ WD sequence and fn 6 vn for all n > 1, it follows P that V .z/ and F .z/ are well defined for 0 < z < 1. The renewal equation vn D jnD1 fj vn j implies that V .z/ D 1 C F .z/V .z/, hence V .z/ 1 F .z/ D 6 1: V .z/ P By letting z ! 1, it follows that 1 nD1 fn 6 1.
10.1 Special Bernstein functions
99
Pn Define the sequence .rn /n>0 by r0 WD 1 and rn WD 1 j D1 fk , n > 1. Clearly, .rn /n>0 is a non-increasing sequence of non-negative numbers. Note that rn 1 rn D fn for all n > 1. Hence, for all n > 1, vn D
n X
fj vn
j
D
j D1
D
n X
.rj
1
rj
1 vn
j D1 n X
rj / vn
j
j D1
D
n 1 X
j
n X
rj vn
j
rj vn
j:
j D1
rj vn
1 j
j D0
n X j D1
P P This implies that jnD0 rj vn j D jnD01 rj vn 1 j for all n > 1. But for n D 1 we P P have that jnD01 rj vn 1 j D r0 v0 D 1. This proves that jnD0 rj vn j D 1 for all n > 0. N is absolutely continuous on .0; 1/. If the Lemma 10.15. Suppose that x 7! .x/ total mass .0; 1/ D 1 or if b > 0, then the potential measure U is absolutely continuous. If the total mass .0; 1/ < 1 and b D 0, then U j.0;1/ is absolutely continuous. Proof. Assume first that a D 0. If b > 0, then it is well known that U is absolutely continuous, see e.g. [36, Section III.2, Theorem 5]. Assume that .0; 1/ D 1. Since .x/ N is absolutely continuous, by [250, Theorem 27.7] the transition probabilities of S are absolutely continuous and therefore U is absolutely continuous. If a > 0, then the potential measure of the killed subordinator is equal to the apotential measure of the (non-killed) subordinator, hence again absolutely continuous, see e.g. [250, Remark 41.12]. Assume now that .0; 1/ < 1 and b D 0. Since x 7! .x/ N is absolutely continuous, we have .dx/ D m.x/ dx for some function m. Let c WD .0; 1/. The transition probability at time t of the non-killed subordinator is given by t D
1 X
e
kD0
tc
t k ?k : kŠ
Here and in the rest of this proof ?k stands for the k-fold convolution of , and ?0 D ı0 . Therefore, the potential measure of the killed subordinator is equal to Z 1 U D e at t dt 0 ! Z 1 1 k X at tc t ?k D e e dt kŠ 0 kD0
100
10 Special Bernstein functions and potentials
D
Z 1 X ?k 1 e kŠ 0
.aCc/t k
t dt
kD0
?k 1 1 X 1 ı0 C : D aCc aCc aCc kD1
This shows that U j.0;1/ is absolutely continuous with the density uD
?k 1 m 1 X : aCc aCc kD1
N implies that .x/ N is absolutely Proof of Theorem 10.11. The log-convexity of .x/ continuous on .0; 1/. By Lemma 10.15 we know that the density of U exists if .0; 1/ D 1 or b > 0. We choose a version of u such that lim sup h!0
U.x; x C h/ D u.x/ for all x > 0: h
(10.17)
Because of the log-convexity, N is strictly positive everywhere. This excludes the case where a C .x; 1/ D 0 for some x > 0. Fix c > 0 and define a sequence .vn .c//n>0 by b=c C .c/ N .nc N C c/ v0 .c/ WD D 1; vn .c/ WD ; n > 1: N N b=c C .c/ b=c C .c/ Clearly 0 < vn .c/ 6 1 for all n > 0. Moreover, vn .c/2 6 vn 1 .c/vnC1 .c/ for all n > 1. Indeed, for n > 2 this is equivalent to .nc N C c/2 6 N .n 1/c C c N .n C 1/c C c which is a consequence of the log-convexity of . N For n D 1 we have .2c/ N 6 .c/ N .3c/ N 6 b=c C .c/ N .3c/: N By Lemma 10.14, there exists a non-increasing sequence .rn .c//n>0 such that n X
rj .c/vn
j .c/
D1
for all n > 0:
(10.18)
j D0
Define
rn .c/ ; n > 0: b=c C .c/ N Inserting this expression into (10.18) we get for all n > 0 un .c/ WD
n
X b un .c/ C uj .c/N .n c j D0
j /c C c D 1:
(10.19)
101
10.1 Special Bernstein functions
Multiplying (10.19) by ce 1 X
b
e
.nC1/c
.nC1/c
un .c/ C
nD0
and summing over all n > 0, we obtain
1 X n X
ce
.nC1/c
uj .c/N .n
j /c C c
nD0 j D0
D
1 X
ce
.nC1/c
:
nD0
This can be simplified to be
c
1 X
e
nc
un .c/ C
nD0
1 X
1 X
! e
nc
un .c/
c
nD0
! nc
e
.nc/ N D
nD1
ce 1 e
c c
:
P Define a measure Uc on .0; 1/ by Uc WD 1 nD0 un .c/ ınc . Then the above equation becomes Z 1 1 X ce c t c nc : e d Uc .t/ be C ce .nc/ N D 1 e c 0 nD1 Let c # 0. The right-hand side converges to 1, while Z 1 X ce nc .nc/ N D b C lim be c C c#0
Z lim
c#0 Œ0;1/
e
t
.t/ N dt D f ./:
e
t
d U.t/
0
nD1
Therefore
1
t
e
1 d Uc .t/ D D f ./
Z Œ0;1/
which means that Uc converges vaguely to U . Since U is absolutely continuous, this implies that for all x > 0 and all h > 0, Z xCh lim Uc .x; x C h/ D u.t/ dt: c#0
x
Now suppose that 0 < x < y and choose h > 0 such that x < x C h < y. Moreover, let c be such that none of the points x; x C h; y; y C h is an integer multiple of c. By the monotonicity of .un .c//n>0 , it follows that Uc .y; y C h/ 6 Uc .x; x C h/: Let c go to zero along values such that the points x; x C h; y; y C h are not integer multiples of c. It follows that U.y; y C h/ 6 U.x; x C h/ and (10.17) guarantees that u.y/ 6 u.x/ for all x < y.
102
10 Special Bernstein functions and potentials
We give now two sufficient conditions such that a Bernstein function is not special. R Proposition 10.16. Let f ./ D b C .0;1/ .1 e t / .dt/, b > 0, be a Bernstein function. If has bounded support, then f cannot be special. Proof. Assume that f is a special Bernstein function and .t0 ; 1/ D 0 for some t0 > 0. Let f ? ./ WD =f ./ with corresponding subordinator T D .T t / t >0 . Denote by V be the potential measure of T and by v the density of V j.0;1/ . Then v.t/ D .t; 1/ D 0 for all t > t0 . But this implies V .t0 ; 1/ D 0 which is impossible. R Proposition 10.17. Let f ./ D a C .0;1/ .1 e t / .dt/, a > 0, be a Bernstein function. Assume that the Lévy measure is nontrivial and that .0; t0 D 0 for some t0 > 0. Then f is not special. Proof. Suppose, on the contrary, that f is a special Bernstein function. Then the conjugate function f ? ./ D =f ./ is of the form (10.2). The potential density of the corresponding subordinator T is given by the formula v.t/ D a C .t; 1/. In particular, v.t/ D a C .t0 ; 1/ DW for 0 < t < t0 . It follows from (10.4) that b ? D 1= > 0. On the other hand, from Theorem 10.9 (with the roles of u and v reversed), we have that Z t b ? v.t/ C u.s/v.t s/ ds D 1 for all t > 0: 0
For 0 < t < t0 we have v.t/ D , so Z t 1C u.s/ ds D 1;
0 < t < t0 :
0
Rt It follows that 0 u.s/ ds D 0 for all 0 < t < t0 , and since u is non-increasing we have u 0. Thus U.dt/ D b ? ı0 , implying that f D 1=b ? . But this contradicts the assumption that the Lévy measure is not trivial. The last two propositions clearly show that SBF is strictly smaller than BF. A typical example of a Bernstein function which is not special is f ./ D 1 e . The corresponding subordinator is a Poisson process with rate > 0. The next example shows that the family SBF is strictly larger than CBF. Example 10.18. (i) Define ´ v.t/ WD
t t
˛; ˇ;
0 < t < 1; 16t <1
where 0 < ˇ < ˛ < 1. Obviously, v is non-increasing, log-convex and satisfies R1 v.t/ dt < 1. By Corollary 10.12, v is the potential density of a special subordi0 nator. Since v is not completely monotone—it is clearly not C 1 —, the corresponding Laplace exponent is not a complete Bernstein function.
10.1 Special Bernstein functions
103
(ii) For 0 < ˛ < 1 define ´ t ˛; v.t/ WD 1;
0 < t < 1; 1 6 t < 1:
R1 Again, v is non-increasing, log-convex and satisfies 0 v.t/ dt < 1. Hence, there exists a special subordinator T D .T t / t >0 with potential measure V such that v is the density of V . Let f ? be the Laplace exponent of T , and define f ./ WD =f ? ./. R Since v.1/ D 1, we have that f ./ D 1C .0;1/ .1 e t / .dt/ with Lévy measure .dt/ D m.t/ dt, where ´ ˛t m.t/ WD 0;
˛ 1;
0 < t < 1; 1 6 t < 1:
Note that the Lévy measure has bounded support. This does not contradict Proposition 10.16 since we have a non-zero killing term of f equal to 1. This example shows that for f 2 BF it may happen that 7! a C f ./ 2 SBF for some a > 0, while f … SBF. (iii) This example is similar to the previous one, but the Lévy measure is finite. Let ´ v.t/ WD
e1 t ; 1;
0 < t < 1; 1 6 t < 1:
R1 Again, v is non-increasing, log-convex and satisfies 0 v.t/ dt < 1. Hence, there exists a special subordinator T D .T t / t >0 with potential measure V such that v is the density of V . Let f R? be the Laplace exponent of T , and define f ./ WD =f ? ./. Then f ./ D 1 C .0;1/ .1 e t / .dt/ with Lévy measure .dt/ D m.t/ dt, where ´ e 1 t ; 0 < t < 1; m.t/ WD 0; 1 6 t < 1: As already pointed out, the class SBF does not have good structural properties. Here are a few positive results. Proposition 10.19.
(i) SBF is a cone closed under pointwise convergence.
(ii) f 2 SBF if, and only if, 7! b C f ./ 2 SBF for all b > 0. (iii) f 2 SBF if, and only if,
tf t Cf
2 SBF for all t > 0.
(iv) f 2 SBF if, and only if, 7! f . C c/ 2 SBF for all c > 0.
104
10 Special Bernstein functions and potentials
Proof. (i) follows immediately from the fact that BF is a cone which is closed under pointwise convergence. (ii) Let f 2 SBF and b > 0. Define h./ WD
: 1 C b
Then h 2 BF, and by the composition result for Bernstein functions, cf. Corollary 3.7 or Theorem 5.19, it follows for the conjugate f ? ./ D =f ./ that h ı f ? ./ D
f ? ./ D 2 BF: ? 1 C bf ./ b C f ./
Since 7! b C f ./ 2 BF, we know that 7! b C f ./ 2 SBF, too. The converse statement follows from (i) by letting b ! 0. (iii) Let f 2 SBF and t > 0. As in (ii), tf =.t C f / 2 BF. Further, tf ./ t Cf ./
D
t C f ./ D C 2 BF; tf ./ f ./ t
implying that tf =.t C f / 2 SBF. The converse follows from (i) by letting t ! 1. (iv) First note that if f 2 BF, g 2 CM and f g > 0, then f g 2 BF which is easily seen from the definition of BF and CM. Let now f 2 SBF and c > 0. Then Cc D f . C c/ f . C c/
c > 0: f . C c/
Since 7! . C c/=f . C c/ 2 BF and 7! c=f . C c/ 2 CM, we conclude that =f . C c/ is a Bernstein function which proves the claim. The converse follows by letting c ! 0. Remark 10.20. We do not know whether SBF is a convex cone. It is even unclear whether a C f 2 SBF, a > 0, for f 2 SBF. Let f 2 SBF. Then a C f 2 SBF if, and only if, 7! .a C f .//= 2 P. We can also use potential densities to characterize when a C f 2 SBF. Assume, for simplicity, that f 2 SBF is of the form Z 1 f ./ D e t .t/ N dt: 0
Then v.t/ D .t/ N is the potential density of the conjugate function f ? ./ D =f ./. For a > 0, Z 1 a C f ./ D e t .v.t/ C a/ dt; 0 showing that a C f 2 SBF if, and only if, v.t/ C a is a potential density.
10.2 Hirsch’s class
10.2
105
Hirsch’s class
In this section we describe another family of completely monotone functions which was introduced by F. Hirsch in [137]. It turns out that this class, H, is a rich intermediate class between the Stieltjes functions S on the one side, and the completely monotone functions of the form 1=f where f 2 SBF on the other side. In some sense H is the largest known family of concrete examples for potentials. Definition 10.21. We call a function f 2 CM a Hirsch function if for all > 0 the sequence . 1/n .n/ f ./ nŠ n>0 is log-convex in the sense of Definition 10.10. The set of all Hirsch functions will be denoted by H. Proposition 10.22. The set H is a convex cone closed under pointwise convergence. Proof. The convexity of H follows from the fact that log-convex sequences form a convex cone. Indeed, let .an /n>0 and .bn /n>0 be two log-convex sequences. Then it holds for all n > 1 that an2 6 an 1 anC1 and bn2 6 bn 1 bnC1 . Therefore .an C bn /2 D an2 C bn2 C 2an bn p 6 an 1 anC1 C bn 1 bnC1 C 2 an 1 anC1 bn 1 bnC1 6 an 1 anC1 C bn 1 bnC1 C an 1 bnC1 C anC1 bn D .an
1
1
C bn 1 /.anC1 C bnC1 /:
Since complete monotonicity and log-convexity are preserved under pointwise convergence, H is closed under pointwise convergence. Theorem 10.23. R 1 Suppose that u W .0; 1/ ! .0; 1/ is non-increasing, log-convex and satisfies 0 u.t/ dt < 1, and let c > 0. Define a measure U by U.dt/ D cı0 .dt/ C u.t/ dt:
(10.20)
Then L U 2 H. Conversely, every f 2 H is the Laplace transform of a measure U of the form (10.20). Proof. Suppose that U is given by (10.20) and that the function u is twice continuously differentiable. For every > 0, the function g defined by g .s/ D e
s
u.s/;
s > 0;
is also logarithmically convex and of class C 2 , hence .g0 /2 6 g g00 :
106
10 Special Bernstein functions and potentials
Let f ./ WD L .uI / D
1
Z
e
s
u.s/ ds;
> 0:
0
Then for n > 1, . 1/n .n/ f ./ D nŠ As g0 6
q
1
Z 0
sn g .s/ ds D nŠ
1
Z 0
s nC1 g 0 .s/ ds: .n C 1/Š
g g00 , we find by the Cauchy–Schwarz inequality that
. 1/n .n/ f ./ nŠ
2
1
Z 6 0
s nC1 g .s/ ds .n C 1/Š
1
Z 0
s nC1 g 00 .s/ ds .n C 1/Š
Z 1 n 1 s s nC1 D g .s/ ds g .s/ ds .n C 1/Š .n 1/Š 0 0 . 1/nC1 .nC1/ . 1/n 1 .n 1/ f ./ f ./ ; D .n C 1/Š .n 1/Š Z
1
showing that f 2 H. Every non-increasing log-convex function u W .0; 1/ ! .0; 1/ is the supremum of a sequence of C 2 functions un W .0; 1/ ! .0; 1/ which are nonincreasing and log-convex. For such functions we have proved that L un 2 H. By the monotone convergence theorem it follows that L un increases pointwise to L u. By Proposition 10.22 it follows that L u 2 H. Since positive constants are in H, and since H is a convex cone, we see that L U 2 H. Now we prove the converse statement. Let f 2 H CM and define fn ./ WD
. 1/n n nC1 .n/ n f ; nŠ
> 0;
(compare with (1.8)). Then fn is C 1 and strictly positive. We are going to prove that it is log-convex, by showing that .log fn /00 ./ > 0. We first compute n C 1 2n f .nC1/ n C 3 .log f / ./ D 2 f .n/ n n 2 f .nC2/ n C 2 f .n/ n
00
n f .nC1/ n 2 f .n/ n
By the inequality f .n/
n
f .nC2/
n
>
n C 2 .nC1/ n 2 f ; nC1
!2 :
10.2 Hirsch’s class
107
we obtain !2 1 n C 1 2n f .nC1/ n n f .nC1/ n C .log f / ./ > C 3 2 f .n/ n n C 1 2 f .n/ n !2 p n n C 1 f .nC1/ n > 0: D C p f .n/ n 2 n C 1 00
The next step is to show that fn is non-increasing. Since f 2 CM, there exists a measure U on Œ0; 1/ such that f D L U . Assume that U is bounded. Differentiating n times under the integral sign yields Z . 1/n e t U.dt/: f .n/ ./ D Œ0;1/
Using the elementary inequality e t .t/n 6 .n=e/n , ; t > 0, and dominated convergence we see lim f .n/ ./nC1 D 0: !0
Hence
. 1/n .n/ n n nC1 f D 0: !1 nŠ
lim fn ./ D lim
!1
For a general measure U , Since fn is convex, this implies that it is non-increasing. R t pick c > 0 and set fc ./ WD f . C c/ D Œ0;1/ e e ct U.dt/. Then fc 2 H with a bounded measure e ct U.dt/. By the proof above, fc;n is non-increasing. As fn ./ D limc!0 fc;n ./, > 0, it follows that fn is non-increasing. Let a WD lim!1 f ./. Then U D aı0 C U0 where U0 D U j.0;1/ . Moreover, if fQ WD f a, then the proof of Theorem 1.4 shows that fQn .x/ dx converges weakly to U0 .dx/ as n ! 1. Since fn D fQn , n > 1, we get that fn .x/ dx converges weakly to U0 .dx/. Since fn0 6 0 and fn00 > 0, it follows that DU0 6 0 and D 2 U0 > 0 where we take derivatives in the distributional sense. Hence, there exists a convex nonincreasing function u W .0; 1/ ! .0; 1/ such that U0 .dx/ D u.x/ dx. In particular, u is continuous. By the result in [289, p. 288] it follows that limn!1 fn .x/ D u.x/ for all x > 0. Since the pointwise limit of log-convex functions is again log-convex, this finishes the proof. We record several simple consequences of the preceding theorem. Corollary 10.24.
(i)
1 H
SBF
and
H P.
(ii) If h 2 H, then h./ 2 SBF. (iii) If f 2 BF and N is log-convex, then f ./= 2 H. (iv) S H.
108
10 Special Bernstein functions and potentials
Proof. (i) Let g 2 H . By Theorem 10.23, g D L U for a measure U of the form (10.20). By Corollary 10.12, U is the potential measure of a special subordinator, i.e. L U D 1=f for f 2 SBF. Thus, 1=g D f 2 SBF and, in particular, g 2 P. (ii) Let f WD 1= h. By (i), f 2 SBF, and therefore h./ D =f ./ 2 SBF. (iii) By (10.14) we have Z 1 f ./ D b C e t .t/ N dt D L bı0 .dt/ C .t/ N dtI 0
which proves the claim. (iv) Let g 2 S. By Theorem 7.3, g D 1=f where f 2 CBF. By Remark 10.6, the potential measure U of f is of the form U.dt/ D cı0 .dt/ C u.t/ dt with u 2 CM. Since completely monotone functions are logarithmically convex, Theorem 10.23 yields L U 2 H. But L U D g. Remark 10.25. In [29] there is a proof of Corollary 10.24(i), H P, which does not rely on Theorems 10.11 and 10.23. By using this fact and Theorem 10.23 one can give an alternative proof of Theorem 10.11. Indeed, suppose that f 2 BF, f ./ D R a C b C .0;1/ .1 e t / .dt/ and that N is log-convex. Define the measure V .dt/ WD bı0 .dt/ C v.t/ dt where v.t/ D .t/. N Then L V 2 H P, and f ./ D L V ./. Therefore, =f ./ D 1=L V ./ 2 BF, proving that f 2 SBF. Remark 10.26. (i) It is shown in [262, Remark 3.5] that there exists a special Bernstein function f such that the density u of U j.0;1/ is not continuous. This shows that 1=H is strictly contained in SBF. (ii) Suppose that f 2 SBF such that
f
2 H. Let a > 0. Then
f ./ a f ./ C a D C 2 H P; implying that =.f ./ C a/ 2 BF, i.e. f C a 2 SBF. Compare with Remark 10.20. At the end of this section we point out a unified way to describe some of the considered classes of functions. Consider the family ® ¯ f W f D L U; U.dt/ D cı0 C u.t/ dt CM; R1 where c > 0 and u W .0; 1/ ! .0; 1/ such that 0 u.t/ dt < 1. Different choices of u result in different subfamilies of completely monotone functions. More precisely, (i) u 2 CM if, and only if, L U 2 S; (ii) u is non-increasing and log-convex if, and only if, L U 2 H; (iii) u is non-increasing and is a potential density if, and only if, L U 2 (iv) u is non-increasing if, and only if, L .U I / 2 BF.
1 SBF ;
10.2 Hirsch’s class
109
Statements (i), (ii) and (iii) are proved, respectively, in Remark 10.6, Theorem 10.23 and Theorem 10.3. For the last statement note that if u is non-increasing, then it is the tail of a measure , u.t/ D .t/. N Thus Z 1 Z 1 t L .U I / D c C e u.t/ dt D c C e t .t/ N dt 2 BF: 0
0
The converse is proved similarly. Hence, BF
1 SBF
CM;
SH
1 BF and all inclusions are strict. For the second inclusion see Remark 10.26(i), and for the third notice that SBF is strictly contained in =BF and BF, respectively. Comments 10.27. Section 10.1: The term special Bernstein function was introduced in [261], although the notion itself is encountered in the literature earlier. Theorem 10.3 is essentially contained in Bertoin [37, Corollaries 1 and 2] who attributes the result to Van Harn and Steutel [283]. Our presentation follows [261] where the result was rediscovered. Theorem 10.9 also comes from [261]. Special Bernstein functions were used in [195] to characterize the scale functions of one-dimensional Lévy processes having only negative jumps, and in [196] to study de Finetti’s optimal dividend problem. Log-convexity of the tail N of the Lévy measure was studied by J. Hawkes in [126, Theorem 2.1]. Theorem 10.11, cf. [262], is a slight extension as it allows for the killing term, the drift term, and finite Lévy measure. Lemma 10.14 appears also in [126] with a proof having a minor gap (namely, it works P only for the case j1D1 fj D 1). The conclusion of the lemma, equation (10.15), is a discrete version of Chung’s equation, see [70]. Examples 10.18 and Propositions 10.16 and 10.17 are from [262], the proof of the latter is new. One direction of Proposition 10.19(iv) is proved in [195] where also the corresponding Lévy measure is identified. Section 10.2: The class H was introduced by F. Hirsch in [136] and [137]. The starting point of his investigations is the problem to find a structurally well-behaved family of functions which operate on the (abstract) potential operators in the sense of Yosida [296, Chapter XIII.9]; these are densely defined, injective operators V such that A D V 1 is the generator of a strongly continuous contraction semigroup, cf. Chapter 12 below. Although the Laplace transform induces a bijection between Hunt kernels on the half-line Œ0; 1/ (leading to potential operators) and the family of potentials P, see e.g. [135, page 175], the set P lacks nice structural properties. Hirsch shows that the family H P is a convex cone which allows to define a symbolic calculus on (abstract) potential operators along the lines of Faraut’s symbolic calculus [96]. See also the Comments 2.5, 5.21 and 6.12. Theorem 10.23 is from [137, Théorème 2], our proof follows the presentation in Berg and Forst [29, Section 14].
Chapter 11
The spectral theorem and operator monotonicity
In this chapter we look at applications of complete Bernstein functions in operator theory on Hilbert spaces. First we give a proof of the spectral theorem for self-adjoint operators on a Hilbert space which uses the Stieltjes representation of complete Bernstein functions. Then we prove Löwner’s theorem which says that the family of complete Bernstein functions coincides with the family of non-negative operator monotone functions on .0; 1/.
11.1
The spectral theorem
A surprising consequence of the representation formulae for complete Bernstein functions is a simple proof of the spectral theorem for self-adjoint operators on Hilbert spaces. This was first observed by Doob and Koopman [85] and Lengyel [200]. The paper by Nevanlinna and Nieminen [224] contains a full account of this approach and its extensions. Our exposition follows these lines; the monograph by Kato [168] will be our standard reference for spectral analysis in Hilbert spaces. Let H be a complex Hilbert space with scalar product h; i and norm k k. We assume that the scalar product is linear in the first, and skew-linear in the second argument. A linear operator A W D.A/ ! H is said to be self-adjoint if D.A/ H is dense and .A; D.A// D .A ; D.A //. The resolvent set %A consists of all 2 C such that the operator A WD id A has a bounded inverse which we denote by R WD . id A/ 1 WD . A/ 1 ; the operators .R /2%A are the resolvent of A. It is well known that the resolvent set %A is open. The set A WD C n %A is called the spectrum of A. All self-adjoint operators A have real spectrum A R and their resolvents satisfy 1 1 kR uk 6 kuk 6 (11.1) kuk; 2 %A ; u 2 H: dist.; A / jIm j For ; z 2 %A the following resolvent equation holds R
Rz D .z
/Rz R
(11.2)
which is easily seen from R D R .z A/Rz D R ..z / C . A//Rz . Since 7! hR u; vi is continuous, the resolvent equation tells us R Rz u; v D lim hRz R u; vi D hR R u; vi: (11.3) lim z z! z!
11.1 The spectral theorem
111
This means that hR u; vi, u; v 2 H, is complex differentiable for all 2 %A , hence it is analytic. Recall that a self-adjoint operator .A; D.A// is dissipative if hAu; ui 6 0
for all u 2 D.A/:
(11.4)
Lemma 11.1. Let .A; D.A// be a self-adjoint operator on H. Then A is dissipative if, and only if, the following holds ku
Auk > kuk
for all u 2 D.A/; > 0:
k.
A/uk2 D 2 kuk2
(11.5)
Proof. Clearly,
A/uk2 > 2 kuk2 and (11.5) follows. Conversely,
If hAu; ui 6 0 we see that k. under (11.5) we have 2 kuk2
2hAu; ui C kAuk2 :
2hAu; ui C kAuk2 > 2 kuk2
or 2hAu; ui 6 kAuk2 . Since can be arbitrarily large, this is only possible if hAu; ui 6 0 and (11.4) follows. Proposition 11.2. Let .A; D.A// be a self-adjoint operator on H. Then A is dissipative if, and only if, the spectrum A is contained in . 1; 0. Proof. First we suppose that A . 1; 0. Since > 0 is in the resolvent set, we may use (11.1) with D and u D . A/w, w 2 D.A/, to get kwk D kR .
A/wk 6
1 kw dist.; A /
Awk 6
1 kw
Awk:
This proves dissipativity. Now we suppose that A is dissipative and we want to show that A . 1; 0. For any > 0, let v 2 ..A /.D.A///? . Then v 2 D.A/ and Av D v since A is selfadjoint. Hence kvk2 D hAv; vi 6 0, which gives v D 0. Thus .A /.D.A// D H and consequently A . 1; 0. From now on we will assume that A is a dissipative self-adjoint operator. Lemma 11.3. Let .A; D.A// be a dissipative self-adjoint operator on H. For every u 2 H the function f ./ WD hR u; ui, 2 C n . 1; 0, is (the extension of) a complete Bernstein function such that f ./ D hR u; ui 6 kuk2
for all > 0; u 2 H:
112
11 The spectral theorem and operator monotonicity
Moreover, lim hR u; vi D hu; vi;
!1
u; v 2 H;
(11.6)
and there exists a uniquely determined finite measure E D Eu;u supported in . 1; 0 such that Eu;u . 1; 0 D kuk2 and Z 1 hR u; ui D (11.7) Eu;u .dt/; 2 C n . 1; 0: t . 1;0 Proof. It is clear that f ./ is analytic on %A . Note that ˝ ˛ f ./ D . A C A/R u; u D hu; ui C hAR u; ui:
(11.8)
Setting u D . A/ for a suitable D R u 2 D.A/ and D C i, we conclude that ˝ ˛ ˝ ˛ N f ./ D R . A/; . A/ D ; . A/ D h; i h; Ai: Thus Im f ./ D
Im h; Ai > 0 for Im > 0, and for D > 0 we see f ./ D 2 h; i
h; Ai > 0:
From (11.3) and (11.8) we get d d d f ./ D hAR u; ui D hR u; Aui D d d d D
hR R u; Aui hR u; AR ui > 0:
Therefore, f .0C/ D inf>0 f ./ < 1 exists, and Theorem 6.2(iv) proves that f 2 CBF; in particular, Z .dt/ f ./ D a C b C C t .0;1/ R where a; b > 0 and is a measure on .0; 1/ such that .0;1/ .1 C t/ 1 .dt/ < 1. The Cauchy–Schwarz inequality and the resolvent estimate (11.1) show for any self-adjoint operator .A; D.A// on H and u 2 D.A/ 1 kAuk kuk D 0: lim jhARi u; uij 6 lim kRi Auk kuk 6 lim !1 !1 !1 Thus, lim f .i/ D hu; ui C lim hARi u; ui D kuk2
!1
!1
and we find from the integral representation of f 2 CBF that Z 2 Re f .i/ D a C .dt/: 2 2 .0;1/ C t
11.1 The spectral theorem
113
Monotone convergence now shows that kuk2 D lim f .i/ D a C .0; 1/: !1
On the other hand, Z Im f .i/ D b C
.0;1/
t .dt/; 2 C t 2
so that lim!1 f .i/ D kuk2 combined with the dominated convergence theorem proves that b D 0. This shows Z .dt/; a C .0; 1/ D kuk2 : f ./ D a C .0;1/ C t Moreover, Z f ./ D a C
.0;1/
.dt/ 6 a C .0; 1/ D kuk2 ; Ct
and we can use monotone convergence to get lim hR u; ui D lim f ./ D kuk2 ;
!1
!1
u 2 H:
A standard polarization argument proves then (11.6). To see (11.7), set Eu;u .I / WD ı0 .I / C . I / for all Borel sets I . 1; 0. The uniqueness of the measure Eu;u follows from the uniqueness of the measure in the Stieltjes representation of complete Bernstein functions. With a simple polarization argument we can extend (11.7) to Z 1 hR u; vi D Eu;v .dt/; 2 C n . 1; 0; u; v 2 H: t . 1;0 Since Eu;u is uniquely determined by u, the complex-valued measure Eu;v is uniquely determined by u and v, and Eu;v depends linearly on u and skew-linearly on v; moreover, Eu;v D E v;u is skew-symmetric and Eu;v has total variation less or equal than kuk kvk. Using the inversion formula (6.4) we can actually work out the measure Eu;v . For ˛ < ˇ 6 0 we get the Hellinger–Stone formula Eu;v Œ˛; ˇ/ D . ˇ; ˛ Z 1 D lim h!0C . D
1 h!0C
Im ˇ; ˛
h.s
ih/R sCih u; vi ds s ih
Z
lim
Œ˛;ˇ /
Im hR t Cih u; vi dt
(11.9)
114
11 The spectral theorem and operator monotonicity
at all continuity points ˛; ˇ of 7! Eu;v . 1; /. Note that this formula is still valid for ˛; ˇ > 0 with Eu;v Œ˛; ˇ/ D 0; this allows to extend Eu;v Œ˛; ˇ/ trivially by 0 onto the positive real line. If I . 1; 0 is a Borel set, this shows that .u; v/ 7! Eu;v .I / is a skew symmetric sesquilinear form in the Hilbert space H. By a standard argument, see Lengyel [200] or Lax [199, Chapter 32], we deduce that there exists a bounded self-adjoint operator E.I / such that ˝ ˛ Eu;v .I / D E.I /u; v ; u; v 2 H; I . 1; 0 Borel: This shows that (11.7) can be written as Z ˛ 1 ˝ hR u; vi D E.dt/u; v ; t . 1;0
2 C n . 1; 0; u; v 2 H:
From this point onwards we can argue as usual: one concludes that .E. 1; //2R is a spectral resolution of the operator A and proves the spectral theorem for (dissipative) self-adjoint operators. Theorem 11.4. Let .A; D.A// be a dissipative self-adjoint operator on H. Then there exists an orthogonal projection-valued measure E on the Borel sets of R with support A such that for all Borel sets I; J R (i) E.;/ D 0, E.R/ D id; (ii) E.I \ J / D E.I /E.J /; (iii) E.I / W D.A/ ! D.A/ and AE.I / D E.I /A; R R (iv) Au D A E.d/u for u 2 D.A/ D ¹u 2 H W A 2 hE.d/u; ui < 1º. R Note that kAuk2 D A 2 hE.d/u; ui. For ˆ W . 1; 0 ! R one can define the function ˆ.A/ of the operator A by Z ˆ.A/u WD ˆ./ E.d/u; (11.10) . 1;0
² Z 2 D ˆ.A/ WD u 2 H W kˆ.A/uk D
³ ˝ ˛ jˆ./j E.d/u; u < 1 : (11.11) 2
. 1;0
Example 11.5. Let .A; D.A// be a dissipative self-adjoint operator on H. Then A generates a semigroup of linear operators .T t / t >0 which is strongly continuous, i.e. t 7! T t u is a continuous function from Œ0; 1/ to H, and contractive, i.e. kT t uk 6 kuk. Indeed: Let E.d/ be the spectral resolution of the operator A. Then Z T t u D e tA u D e t E.d/u; u 2 H; t > 0; . 1;0
115
11.1 The spectral theorem
and by Theorem 11.4 we get for all u; v 2 H and all s; t > 0
Z
hT t Ts u; vi D T t
e Z
. 1;0
Z D
E.d/u; v
. 1;0
Z D
s
˝ ˛ e t e s E.d/u; E.d /v . 1;0
˝ ˛ e .t Cs/ E.d/u; v . 1;0
D hTsCt u; vi which shows that .T t / t >0 is a semigroup. That t 7! T t u, u 2 H, is continuous in the Hilbert space topology follows directly from the continuity of t 7! e t , 2 . 1; 0, and the fact that Z ˝ ˛ 2 .e t 1/2 E.d/u; u : kT t u uk D . 1;0
In a similar way we deduce from the fact that e t 6 1, t > 0 and 2 . 1; 0, that kT t uk 6 kuk which proves that T t is a contraction operator. Example 11.6. Let .A; D.A// be a dissipative self-adjoint operator on H and denote by .T t / t>0 the strongly continuous contraction semigroup generated by A. Let f be a Bernstein function given by the Lévy–Khintchine representation (3.2), Z f ./ D a C b C where a; b > 0 and
R
.0;1/ .1
.1
e
t
/ .dt/;
.0;1/
^ t/ .dt/ < 1. Then D.A/ D.f . A// and Z
f . A/u D
au C bAu C
.T t u
u/ .dt/;
.0;1/
u 2 D.A/:
(11.12)
Indeed: Let E.d/ be the spectral resolution of the operator A. The elementary inequality 1 ^ .t/ 6 .1 C /.1 ^ t/, ; t > 0, shows that Z f ./ 6 a C b C .1 C /
.0;1/
.1 ^ t/ .dt/ 6 c .1 C /
for some suitable constant c > 0. Therefore Z Z ˝ ˛ jf . /j2 E.d/u; u 6 c . 1;0
.1 . 1;0
˝ ˛ /2 E.d/u; u
116
11 The spectral theorem and operator monotonicity
which means that D.A/ D.f . A//. The representation (11.12) follows now directly from the integral formula (3.2) for f . For u 2 D.A/ we get from Fubini’s theorem Z f . A/ D f . / E.d/u . 1;0
Z D
Z b C
a . 1;0
.1 .0;1/
Z D au
bAu C
e / .dt/ E.d/u t
Z
e t / E.d/u .dt/
.1 .0;1/
. 1;0
Z D au
bAu C
.u
T t u/ .dt/:
.0;1/
Example 11.7. Let .A; D.A// be a dissipative self-adjoint operator on H, denote by .R / 2%A its resolvent, and let f be a complete Bernstein function. We use the Stieltjes representation (6.5) Z f ./ D a C b C where a; b > 0 and
R
.0;1/ .1
C t/
1 .dt/
.0;1/
.dt/; Ct
< 1. Then D.A/ D.f . A// and
Z f . A/u D
au C bAu C
AR t u .dt/; .0;1/
u 2 D.A/:
(11.13)
Indeed: Since CBF BF, the inclusion D.A/ D.f . A// follows from Example 11.6. Let E.d/ be the spectral resolution of the operator A. Then Z AR t u D
. 1;0
E.d/u; t
u 2 H; t > 0;
defines a bounded operator. Since . /=.t / 6 1 ^ . =t/ for 6 0 and t > 0, we conclude from this that ² ³ 1 kAR t uk 6 min kuk; kAuk ; t > 0: t From the elementary inequality min¹1; sº 6 2s=.1 C s/, s > 0, we get kAR t uk 6 2
1
1 kAuk t kuk C 1t kAuk kuk
kuk D 2
t
kAuk kuk C kAuk kuk
kuk:
(11.14)
11.1 The spectral theorem
117
Let us now determine f . A/. Z ˝ ˛ h f . A/u; ui D f . / E.d/u; u . 1;0
Z D
ahu; ui C bhAu; ui C
. 1;0
Z D
ahu; ui C bhAu; ui C
Z .0;1/
t
.0;1/
Z . 1;0
t
˝ ˛ .dt/ E.d/u; u ˝ ˛ E.d/u; u .dt/
Z D
ahu; ui C bhAu; ui C
.0;1/
hAR t u; ui .dt/:
The change in the order of integration is possible since all integrands are non-negative. The estimate (11.14) tells us that for u 2 D.A/ Z kAR t uk .dt/ kf . A/uk 6 akuk C bkAuk C .0;1/
Z 6 akuk C bkAuk C 2 6 2f
.0;1/
t
kAuk kuk C kAuk kuk
.dt/ kuk
kAuk kuk: kuk
Remark 11.8. Let .A; D.A// be a dissipative self-adjoint operator on H with resolvent .R />0 . By Lemma 11.3 the function 7! hR u; ui is for all u 2 H a complete Bernstein function. Therefore, f ./ WD hR u; ui is a Stieltjes function. Consider the special situation where H D L2 .Rd ; dx/ and where resolvent operators R are integral operators given by kernels R .x; y/, i.e. Z R u.x/ D R .x; y/u.y/ dy; u 2 L2 : Rd
If x 7! R .x; x/ is continuous at x D x0 , then f ./ WD R .x0 ; x0 / is a Stieltjes function. Without loss of generality we can assume that x0 D 0. Consider a sequence un 2 n!1 1 Cc .Rd / of type delta, i.e. un ! ı0 weakly, then “ hR un ; un i D
R .x; y/ un .x/ un .y/ dx dy
n!1
! R .0; 0/
since R is continuous at x D 0. The assertion follows since S is stable under pointwise limits, cf. Theorem 2.2.
118
11 The spectral theorem and operator monotonicity
We have seen in Example 11.5 that A generates a strongly continuous contraction semigroup .T t / t >0 . Obviously Z ˝ ˛ s 7! hTs u; ui D e s E.d/u; u ; u 2 L2 ; . 1;0
is completely monotone. If Ts is an integral operator with kernel ps .x; y/, we can show as above that s 7! ps .x; x/ is completely monotone for all x such that x 7! ps .x; x/ is continuous. A particularly interesting example is given by strongly continuous convolution semigroups or, equivalently, Lévy processes; for details we refer to Jacob [157] Section 3.6 or [158]. In this case, A D .D/ is a pseudo differential operator with symbol which is negative definite in the sense of Schoenberg, cf. (4.7), and Z Z u./ e ix d D u.x C y/ ps .dy/; u 2 Cc1 .Rd /; Ts u.x/ D e s ./ b where b u denotes the Fourier transform and b p s D e s . The resolvent operators are given by Z 1 R u.x/ D b u./ e ix d ; u 2 Cc1 .Rd /: C ./ Since b p s ./ D e s ./ , it is clear that the measure ps .dy/ is for all s > 0 absolutely continuous with density ps 2 L1 if, and only if, e s 2 L1 for all s > 0. In this case, the Riemann–Lebesgue lemma applies and shows that y 7! ps .y/ is continuous. Sufficiency is obvious, necessity follows from the fact that ps=2 2 L1 \ L1 is already an L2 -function. Therefore, 1 e 2s Db p s=2 2 L2 or e
s
2 L1 . This proves that the semigroup and resolvent densities exist and that t 7! p t .0/ 2 CM and 7! R .0/ 2 S
whenever e
11.2
s
2 L1 for all s > 0.
Operator monotone functions
Let .H; h; i/ be a finite or infinite-dimensional real Hilbert space and let A and B be bounded self-adjoint operators on H. If dim H D n, we will identify H with Rn and A; B with symmetric n n matrices. We write B 6 A if B A is dissipative. This is equivalent to saying that hBu; ui 6 hAu; ui for all u 2 H:
(11.15)
11.2 Operator monotone functions
119
As usual we define functions of A by the spectral theorem (in finite or infinite dimension). Definition 11.9. A function f W .0; 1/ ! R is said to be matrix monotone of order n if for all symmetric matrices A; B 2 Rnn with A ; B .0; 1/ B6A
implies f .B/ 6 f .A/:
We write Pn for the set of matrix monotone functions of order n. If f is matrix monotone of all orders n 2 N, we call f operator monotone. In the remaining part of this section we will assume that the operators .A; D.A// and .B; D.B// are dissipative self-adjoint operators on H which are not necessarily bounded. It may happen that the domain D.A/ \ D.B/ of the difference B A of two unbounded operators is not dense in H; this means that (11.15) might not be well defined. To circumvent this, we use quadratic forms. Denote by . A/1=2 the unique positive square root of . A/ defined via the spectral theorem. Then ´˝ ˛ . A/1=2 u; . A/1=2 u ; if u 2 D.QA / D D.. A/1=2 /I QA .u; u/ WD C1; for all other u 2 H defines the quadratic form generated by the operator A. If u 2 D.A/, then we have QA .u; u/ D hAu; ui; this is, in particular, the case for bounded operators. Therefore, 0 6 QA .u; u/ 6 QB .u; u/ 6 C1; u 2 H; (11.16) is the proper generalization of (11.15) for arbitrary dissipative operators. Definition 11.10. Let A and B be dissipative self-adjoint operators on H. If (11.16) holds for the quadratic forms, we say that . B/ dominates . A/ in quadratic form sense and write . A/ 6qf . B/. Note that . A/ 6qf . B/ entails D . B/1=2 D D.QB / D.QA / D D . A/1=2 and that 0 6 . A/ amounts to saying that A is dissipative. Obviously, the condition for f W .0; 1/ ! R T that f . A/ 6qf f . B/ whenever . A/ 6qf . B/ seems to be stronger than f 2 n2N Pn . But we will see later in Theorem 11.17 that these properties are equivalent. A hint in this direction is given by the following lemma. Lemma 11.11. Let .A; D.A// and .B; D.B// be two dissipative self-adjoint operators on H and denote by .RA / 2%A and .RB / 2%B their resolvents. Then the following assertions are equivalent
120
11 The spectral theorem and operator monotonicity
(i) 0 6qf . A/ 6qf . B/; A (ii) 0 6qf RB t 6qf R t for all t > 0; B (iii) 0 6qf . A/RA t 6qf . B/R t for all t > 0.
Proof. (i))(ii) Fix t > 0. For any u 2 H set WD .t WD .t
A/ 1 u 2 D.A/ D.QA / D.QB /; B/ 1 u 2 D.B/ D.QB /:
Since A t is dissipative, we can use the spectral theorem, Theorem 11.4, to define the square root .t A/1=2 ; this is again a self-adjoint operator and D.A/ D.. A/1=2 / D D..t A/1=2 /. Since by assumption .t A/ 6qf .t B/, we get by the Cauchy–Schwarz inequality ˝ .t
˛2 ˝ B/ 1 u; u D .t ˝ D .t ˝ 6 .t ˝ 6 .t ˝ D .t
B/ 1 u; .t
A/
˛2
˛2 A/1=2 ˛ ˝ ˛ A/1=2 ; .t A/1=2 ; .t A/ ˛ ˝ ˛ B/1=2 ; .t B/1=2 .t A/ 1 u; u ˛˝ ˛ B/ 1 u; u .t A/ 1 u; u : A/1=2 .t
B/ 1 u; .t
This proves .t B/ 1 6qf .t A/ 1 . (ii))(iii) We have for all t > 0 and u 2 H ˝ ˛ ˝ . A/RA t u; u D .t
A/RA t u
D hu; ui
˛ tRA t u; u
htRA t u; ui
6 hu; ui htRB t u; ui ˝ ˛ D . B/RB t u; u : (iii))(i) Lemma 11.3 shows that ˝ ˛ ˝ A ˛ lim tRA tR t . A/1=2 u; . A/1=2 u t . A/u; u D t lim !1 ˝ ˛ D . A/1=2 u; . A/1=2 u
t !1
for all u 2 D.QA /. Using a similar argument for tRB t . B/ yields ˝ ˛ ˝ ˛ . A/1=2 u; . A/1=2 u 6 . B/1=2 u; . B/1=2 u :
11.2 Operator monotone functions
121
Theorem 11.12. Let f 2 CBF and let .A; D.A// and .B; D.B// be two dissipative self-adjoint operators on H; denote by .RA /2%A and .RB /2%B the corresponding resolvents. Then . A/ 6qf . B/
implies f . A/ 6qf f . B/:
(11.17)
In particular, f is operator monotone in the sense of Definition 11.9. Proof. We have seen in Example 11.7 that ˝ ˛ ˝ ˛ f . A/u; u D ahu; ui C b . A/u; u C
Z .0;1/
˝ ˛ . A/RA t u; u .dt/
holds for all u 2 D.A/—and even u 2 H if we understand the expression on the right as a quadratic form which is C1 if u 62 D.Qf . A/ /. The operators tR t A are bounded, see Example 11.7, and .0; n/ < 1 for all n 2 N. Therefore, Z hARA t u; ui .dt/ < 1 for all u 2 H; n 2 N: .0;n/
˝ ˛ ˝ ˛ Since limn!1 nRnA Au; u D Au; u on D.A/, we have for u 2 D.A/ Z ˛ ˝ ˝ ˛ ˝ ˛ . A/RA u; u .dt/ f . A/u; u D lim ahu; ui C b nRnA . A/u; u C t n!1
.0;n/
where the expression inside the bracket defines a bounded operator. If we understand this in the sense of quadratic forms, the right-hand side converges to a finite value if, and only if, u 2 D.Qf . A/ /. Analogous assertions hold for the operators B, f . B/ and the quadratic forms generated by them. B Lemma 11.11 shows that h. A/RA t u; ui 6 h. B/R t u; ui for all u 2 H. If we apply this to the limit expression above, we get hf . A/u; ui 6 hf . B/u; ui or, more precisely, 0 6 Qf .
A/ .u; u/
6 Qf .
B/ .u; u/
6 1;
u 2 H;
which means that f . A/ 6qf f . B/. Corollary 11.13. Let f 2 CBF and let .A; D.A// be a dissipative self-adjoint operator on H. Then for all c > 0 it holds that D f . cA/ D D f . A/ and D f .c A/ D D f . A/ : Proof. Assume first that c > 1. Observe that for all ; t > 0 c 6c t C c t C
and
cC c 6 C : t C .c C / t Cc t C
122
11 The spectral theorem and operator monotonicity
Since f 2 CBF is non-decreasing we conclude from this and the Stieltjes representation (6.5) of f that f ./ 6 f .c/ 6 cf ./
and
f ./ 6 f .c C / 6 f .c/ C f ./:
As both 7! f .c/ and 7! f .cC/ are complete Bernstein functions, the assertion follows from (11.11). The argument for 0 < c < 1 is similar. Corollary 11.14. Let f 2 CBF and let .A; D.A// and .B; D.B// be two dissipative self-adjoint operators on H. If D.B/ D.A/, then D.f . B// D.f . A//. Proof. Since A and B are closed operators with D.B/ D.A/ we know from an inequality due to Hörmander, see [296, Chapter II.6, Theorem 2], that there exists a constant c > 0 such that kAuk 6 c kBuk C kuk ; u 2 D.B/: Using the triangle inequality and dissipativity, (11.5), we find on D.B/ .1 C / kAuk 6 c k.B /uk C .1 C /kuk 6 c k.B /uk C k.B
/uk :
With a suitable constant c > 0 we can recast this inequality as . A/2 6qf c2 .
B/2 :
p Setting f D g and ˛ D 1=2 in Corollary 7.12(iii), we see that h./ WD f 2 . / is again a complete Bernstein function. By spectral calculus and Theorem 11.12 we get q q 2 2 2 2 2 2 f . A/ D f . A/ 6qf f c . B/ D f 2 c . B/ ; hence, kf . A/uk 6 kf .c . lary 11.13.
B//uk. Therefore, the claim follows from Corol-
If we use the complete Bernstein functions f ./ D ˛ , 0 < ˛ < 1, we obtain the famous Heinz–Kato-inequality. Corollary 11.15. Let .A; D.A//, .B; D.B// be two dissipative self-adjoint operators on H. Then k. A/1=2 uk 6 k. B/1=2 uk; u 2 D . B/1=2 implies for all ˛ 2 .0; 1/ k. A/˛=2 uk 6 k. B/˛=2 uk;
u 2 D . B/˛=2 :
11.2 Operator monotone functions
123
In the remaining part of this section we will prove that the family of complete Bernstein functions and the family of positive operator monotone functions coincide. Recall that f 2 Pn if for all positive semi-definite symmetric matrices A; B 2 Rnn , B 6qf A implies that f .B/ 6qf f .A/. Let ˛1 ; : : : ; ˛n be the (non-negative) eigenvalues of A and denote by DŒ˛j the n n diagonal matrix with diagonal entries ˛1 ; : : : ; ˛n . By choosing a suitable orthonormal basis we can assume that A D DŒ˛j ; then f .A/ D DŒf .˛j /. Let ˇ1 ; : : : ; ˇn be the eigenvalues of B. There exists an orthogonal n n matrix Q such that B D Q> DŒˇj Q and f .B/ D Q> DŒf .ˇj /Q. The conditions hBx; xi 6 hAx; xi and hf .B/x; xi 6 hf .A/x; xi, x 2 Rn , can be equivalently restated as n X
.Qx/j2 ˇj 6
j D1
and
n X
n X
x 2 Rn ;
xj2 ˛j ;
j D1
.Qx/j2 f .ˇj / 6
j D1
n X
x 2 Rn ;
xj2 f .˛j /;
j D1
respectively. P Define the weighted norm kxk.˛/ WD . jnD1 xj2 ˛j /1=2 and the corresponding operator norm kQxk.ˇ / kQk.˛;ˇ / WD sup : x¤0 kxk.˛/ Then f 2 Pn if, and only if, for every orthogonal n n matrix Q and all x 2 Rn , kQk.˛;ˇ / 6 1
implies that
n X
.Qx/j2 f .ˇj /
n X
6
j D1
xj2 f .˛j /:
(11.18)
j D1
We say that a function f W .0; 1/ ! R is in Pthe set Mn , n 2 N, if for all distinct 1 ; : : : ; 2n > 0 and all a1 ; : : : ; a2n 2 R with j2nD1 aj D 0 2n X
aj
2n X j t 1 > 0 for all t > 0 implies that aj f .j / > 0: j C t
(11.19)
j D1
j D1
Clearly, Mn MnC1 . Since 2n X j D1
2n
X j t 1 D aj aj j C t j D1
j 1 tC t t C j
1 t
2n j 1 X D tC aj ; t t C j j D1
we haveP f 2 Mn if, and only if, for all distinct 1 ; : : : ; 2n > 0 and all a1 ; : : : ; a2n 2 R with j2nD1 aj D 0 2n X j D1
aj
2n X j > 0 for all t > 0 implies that aj f .j / > 0: t C j j D1
(11.20)
124
11 The spectral theorem and operator monotonicity
We explain now yet another way to characterize when f 2 Mn . Denote by ….n/ the family of all polynomials of degree less than or equal to n. For Q distinct 1 ; : : : ; 2n > Q 0 put .t/ WD j2nD1 .t C j / and observe that 0 . k / D j ¤k .j k /. For p 2 ….2n 1/ set ak D ak .p/ WD
p. k / ; k /k
k D 1; : : : ; 2n;
0.
(11.21)
and let a D a.p/ D .ak .p//16k62n 2 R2n . Then 2n
X j p.t/ D aj .t/ t C j
(11.22)
j D1
holds true and shows that p 7! a.p/ defines a linearPbijection from ….2n 1/ onto R2n . By observing that p.0/ D 0 is equivalent to j2nD1 aj .p/ D 0, it follows from (11.20) that f 2 Mn if, and only if, for all p 2 ….2n 1/ with p.0/ D 0, p.t/ > 0 for all t > 0 implies that
2n X
aj .p/f .j / > 0:
(11.23)
j D1 C Lemma 11.16. For every n 2 N, PnC1 MnC .
Proof. Every polynomial p 2 ….2n 1/ with p.0/ D 0 and p.t/ > 0 for all t > 0 can be written as p.t/ D tq12 .t/ C q22 .t/ where q1 ; q2 2 ….n 1/ and q2 .0/ D 0, cf. Akhiezer [2, p. 77]. Because of the linearity of the map (11.21) it suffices to consider two cases: (i) p.t/ D tq 2 .t/; (ii) p.t/ D
q 2 .t/;
q 2 ….n q 2 ….n
1/; 1/; q.0/ D 0.
Relabel 1 ; 2 ; : : : ; 2n > 0 as 0 < ˇ1 < ˛1 < ˇ2 < < ˇn < ˛n . Then 0 . ˇj / > 0 and 0 . ˛j / < 0, j D 1; 2; : : : ; n. (i) Given a polynomial q 2 ….n the polynomial tq 2 .t/ reads tq 2 .t/ D .t/
n X j D1
1/ the partial fractions representation (11.22) of n
yj2
X ˇj ˛j C xj2 t C ˇj t C ˛j
(11.24)
j D1
where yj D
q. ˇj / ; ˇj //1=2
. 0 .
xj D
q. ˛j / ; . 0 . ˛j //1=2
j D 1; : : : ; n:
(11.25)
11.2 Operator monotone functions
125
Observe that (11.25) defines two linear bijections: ˆ W Rn ! ….n 1/, ˆ.x/ D q and ‰ W ….n 1/ ! Rn , ‰.q/ D y. Let Q WD ‰ ı ˆ be the composition of these two maps. Then Q is a linear bijection from Rn to Rn . Moreover, for q D ˆ.x/ and y D Qx, the partial fractions representation (11.24) is valid. By taking t D 0 in (11.24) it follows that n n X X yj2 C xj2 D 0; j D1
j D1
implying By multiplying (11.24) by t and letting t ! 1 we see Pn Pnthat Q2 is orthogonal. 2 C ˛ ˇ C x that y j j D1 j j > 0, i.e. kQk.˛;ˇ / 6 1. Let f 2 Pn . By (11.18), j D1 j n X
yj2 f .ˇj / C
j D1
n X
xj2 f .˛j / > 0
(11.26)
j D1
for all x 2 Rn and y D Qx, which is precisely (11.23). So far we have only used C that f 2 PnC but not the stronger assumption f 2 PnC1 . (ii) For q 2 ….n 1/ with q.0/ D 0 the partial fractions representation (11.22) of the polynomial q 2 .t/ is n X
n
X ˇj q 2 .t/ D yj2 .t/ t C ˇj
j D1
j D1
xj2
˛j t C ˛j
(11.27)
where yj D
q. ˇj / ; ˇj /ˇj /1=2
. 0 .
xj D
.
q. ˛j / ; ˛j /˛j /1=2
0.
j D 1; : : : ; n:
(11.28)
In order to verify (11.23) for p.t/ D q 2 .t/ we have to show that n X
xj2 f .˛j / C
j D1
n X
yj2 f .ˇj / > 0:
(11.29)
j D1
Let 0 < ˛0 < ˇ1 , ˇnC1 > ˛n and .t/ Q D .t C ˛0 /.t/.t C ˇnC1 /. Then t q 2 .t / ˇnC1 ˇnC1 tq 2 .t/ D t C ˛0 .t/ t C ˇnC1 .t/ Q D
n X j D0
nC1
xQj2
X ˇj ˛j C yQj2 t C ˛j t C ˇj j D1
(11.30)
126
11 The spectral theorem and operator monotonicity
with xQj , j D 0; : : : ; n, and yQj , j D 1; : : : ; n C 1, given by the formulae analogous C to (11.28). Let f 2 PnC1 . From part (i) of the proof we conclude that xQ 02 f .˛0 /
n X
xQj2 f .˛j / C
j D1
n X
2 yQj2 f .ˇj / C yQnC1 f .ˇnC1 / > 0:
(11.31)
j D1
Comparing the rational functions in (11.27) and (11.30) we get for j D 1; : : : ; n, lim xQj D xj ;
˛0 !0
and
lim
ˇnC1 !1
yQj D yj :
Since q.0/ D 0, xQ 02 D
q 2 . ˛0 / ˛0 D O.˛02 / as . ˛0 / ˛0 ˇnC1
and since the degree of q is less than or equal to n 2 yQnC1 D
ˇnC1 ˇnC1
˛0 ! 0
1,
q 2 . ˇnC1 / 2 D O.ˇnC1 / as ˇnC1 ! 1: ˛0 . ˇnC1 /
C are non-decreasing and non-negative, hence lim˛0 !0 ˛02 f .˛0 / D 0 All f 2 PnC1 implying that lim˛0 !0 xQ 02 f .˛0 / D 0. 2 If also limˇnC1 !1 f .ˇnC1 /=ˇnC1 D 0, then we can let ˛0 ! 0 and ˇnC1 ! 1 in (11.31) to get (11.29). C Since PnC1 P2C , we can use formulae (11.26) and (11.25) of part (i) of the proof with n D 2, ˇ1 D 1, ˛1 D 2, ˇ2 D ˇ, ˛2 D 2ˇ and q.t/ D t C 2ˇ to arrive at
2ˇ 1 f .1/ ˇ 1 Multiplying with .ˇ 06
1/.ˇ
f .ˇ/ 6 ˇ2
.ˇ
ˇ 1/.ˇ
2/
f .ˇ/ C
2ˇ 2 f .2/ > 0: ˇ 2
2/=ˇ 3 and rearranging yields .2ˇ
1/.ˇ ˇ3
2/
f .1/ C
2.ˇ 1/2 f .2/: ˇ3
Since the right-hand side tends to 0 as ˇ ! 1, we find limˇ !1 f .ˇ/=ˇ 2 D 0. T It remains to verify that n2N MnC CBF. This is now mainly a functional analytic argument. Theorem 11.17. The families of complete Bernstein and positive operator monotone functions coincide: \ CBF D PnC : n2N
11.2 Operator monotone functions
127
In particular, 0 6qf . A/ 6qf . B/ implies 0 6qf f . A/ 6qf f . B/ if, and only T if, f 2 n2N PnC . Proof of Theorem 11.17. Combining Theorem 11.12 and Lemma 11.16 shows that \ \ CBF PnC MnC : n2N
n2N
It is, therefore, enough to show that the right-hand side is contained in CBF. Write .t/ WD .t 1/=. C t/ and consider the set ´ µ X X G WD g W g.t/ D aj j .t/; aj 2 R; j > 0; aj D 0 : finite
finite
Clearly, G C Œ0; 1 and for each f 2
T
C n2N Mn
! ƒf W G ! R;
ƒf
X
aj j
WD
X
aj f .j /
finite
finite
defines a linear functional on G. The defining property (11.19) of the sets Mn just says that ƒf is positive. Moreover, g0 .t/ WD 5 2 .t/
5.t 2 C 1/ 5.t 2 C 1/ > 2 >1 1 .t/ D 2 t C 3t C 2 t C 3t 2 C 3 C 2
is an element from G. Let us show that ƒf is bounded. Pick g 2 G and define s WD sup g. Obviously, g.t/ 6 s C g0 .t/ where s C WD max¹s; 0º. Thus we see that for all h 2 C C Œ0; 1 ƒf .g/ 6 ƒf .s C g0 / D s C ƒf .g0 / 6 sup jg.t/ C h.t/j ƒf .g0 / : t>0
Since the expression g 7! sup t>0 jg.t/ C h.t/j ƒf .g0 / appearing on the right-hand side is a seminorm on C Œ0; 1, we can use the Hahn–Banach theorem to find an extension of ƒf as a continuous linear functional on C Œ0; 1 bounded by the same seminorm. Now evaluate ƒf for h. Then ƒf . h/ 6 kh
hk1 ƒf .g0 / D 0
which shows that ƒf is a bounded, positive linear functional on C Œ0; 1. We can now appeal to the Riesz representation theorem to get Z ƒf .h/ D h.t/ .dt/; h 2 C Œ0; 1 Œ0;1
128
11 The spectral theorem and operator monotonicity
for some finite positive measure on Œ0; 1. Thus, for g.t/ D .t/ f ./
f .1/ D ƒf .g/ D ƒf . /
1 .t/,
ƒf .1 /:
This shows t 1 .dt/ C f .1/ ƒf .1 / Œ0;1 C t Z t 1 D ¹1º C .dt/ C f .1/ Œ0;1/ C t Z
f ./ D
ƒf .1 /:
Observe that the kernel 7! .t 1/=. C t/ is monotonically increasing. Therefore, monotone convergence shows that f .0C/ exists. Since it is positive, we see that R 1 .dt/ 6 f .1/ t ƒf .1 / < 1; in particular, ¹0º D 0. As is finite, this Œ0;1/ shows that Z t 1 f ./ D ˛ C ˇ C .dt/ .0;1/ C t satisfies all conditions of Theorem 6.7, i.e. f 2 CBF. Comments 11.18. Section 11.1: Standard references for the spectral theorem for normal and self-adjoint operators are the monographs by Yosida [296] and Kato [168]. Our exposition owes a lot to Akhiezer and Glazman [3] and, in particular, to Lax [199, Chapter 32]. Lax [199] is one of the few textbook-style presentations of the Doob and Koopman [85] and Lengyel [200] approach to the spectral theorem. The first proof of the spectral theorem (for bounded operators) is due to Hellinger [128] and Hahn [114]. These papers already contain a version of the Hellinger–Stone formula (11.9). The case of unbounded self-adjoint operators was treated by von Neumann [220] and Stone [271]. We follow Doob and Koopman [85], Lengyel [200] and the beautiful paper by Nevanlinna and Nieminen [224]; see also Akhiezer and Glazman [3] or Lax [199]. This approach works also for general, not necessarily spectrally negative, self-adjoint operators if one uses the version of Theorem 6.2 for CBF-like functions preserving the upper half-plane—these functions are not necessarily positive on the positive real line—see Remark 6.11. The Examples 11.5–11.7 also have an interpretation in connection with Bochner’s subordination which will be discussed in Chapter 12. It turns out that in the Hilbert space setting the generator of the subordinate semigroup, Af , f is a Bernstein function, can be identified with the operator f . A/ defined by spectral calculus. An interesting application is the subordination of Dirichlet forms: the subordinate Dirichlet form .Ef ; D.Ef // is generated by f . A/; using the spectral representation of f . A/, the fact that a Bernstein function is non-decreasing and convex and Jensen’s inequality for integrals, it is straightforward to show that E.u; u/ Ef .u; u/ 6 kuk2 f for all u 2 D.E/: 2 kuk For related results we refer to Ôkura [229] and Section 12.3 below. Section 11.2: The best reference on quadratic forms is still Kato [168], in particular Sections VI.2–6. In order to define B 6 A using quadratic ˝ ˛forms one does actually not need that the quadratic form is bounded from below QB .u; u/ > c u; u ; it is also not necessary to require that A B is densely defined, see Davies [72, Section 4.2]. Lemma 11.11 is from [72, Theorem 4.17] and [251, Lemma 5.19].
11.2 Operator monotone functions
129
Theorem 11.12 appears for the first time in Heinz [127], our proof is from [251, Satz 5.20]. The Heinz– Kato inequality, Corollary 11.15, goes back to [127]; we give a different proof based on [72, Chapter 4.2] and [251]. The characterization of matrix monotone and operator monotone functions goes back to Löwner [205] who establishes a determinant criterion (in terms of divided differences) for matrix monotonicity. Section 6 of that paper also contains the representation of matrix monotone P function f of finite order by a discrete Stieltjes-like representation of the form f ./ D a C a0 C jnD11 aj =.aj C /; the limit n ! 1 is discussed and Löwner actually shows that a matrix monotone function (of all orders n) preserves the upper and lower half-planes. Löwner’s technique is similar to the interpolation technique of Pick [236]—this paper is the only one quoted in [205]—but he seems to be unaware of the progress made by Nevanlinna on the integral representation of such functions, see Comments 6.12 and 7.16. Löwner’s paper had a huge impact on the literature and Theorem 11.17 is nowadays called Löwner’s theorem. Several books are devoted to this topic, among them the monographs [84] by Donoghue, [44] and [45] by Bhatia, and the standard treatise by Horn and Johnson [143, 144]. Several quite different proofs of Löwner’s theorem are known: Bendat and Sherman [20] use the Hamburger moment problem; Hansen and Pedersen [117] show, using extreme-point methods, that operator monotone functions have a Nevanlinna–Pick-type representation, see also Bhatia [44]. Both Hansen–Pedersen and Bhatia derive the integral representation formula for functions which preserve order relations of operators with spectrum in Œ 1; 1; the case of operator monotone functions in the sense of Definition 11.10, i.e. for operators with spectrum in Œ0; 1/, can be recovered by mapping Œ 1; 1 to Œ0; 1/ by an affine-linear transformation (which is itself operator monotone). It is possible to determine the extreme points of operator monotone functions (or complete Bernstein functions) directly: if f is operator monotone, then f ./ D
f ./
f .1/ f .1/ C 1
f ./ D g1 ./ C g2 ./; 1
> 0:
Using results from [44] it is possible to show that g1 ; g2 are again operator monotone and that operator monotone functions are two times continuously differentiable. Consider now the set of operator monotone functions with f 0 .1/ D 1. This is a basis of the cone of all operator monotone functions. One can show that jf 00 .1/j 6 2f 0 .1/ D 2, and one has ˛ WD f 00 .1/=2 2 .0; 1/. Since g10 .1/ D f 0 .1/ C f 00 .1/=2 D 1 ˛ and g20 .1/ D f 00 .1/=2 D ˛, we find that f ./ D .1 ˛/g1 ./=.1 ˛/C˛g2 ./=˛. If f is extremal, we conclude that f ./ D g1 ./=.1 ˛/ D g2 ./=˛. This shows that the extremal points of the basis are necessarily of the form f ./ D
f .1/ C
1 ˛ ˛
;
> 0; ˛ 2 Œ0; 1:
The proof by Korányi [179], see also Sz.-Nagy’s remarks [272] and their joint work [180], uses Hilbert space methods and the theory of reproducing kernel spaces. A nice presentation can be found in [84, Chapters X, XI] and [247, Addenda to Chapter 2]. Our proof is a slight simplification of Sparr’s elementary approach [263] which itself is inspired by the theory of interpolation spaces; a related account is given by Ameur, Kaijser and Silvestrov [6]. There is a deep relation between operator monotone functions and operator means. Ando [9] proves that there is a one-to-one relation between the class of operator monotone functions on Œ0; 1/ with f .1/ D 1 and the class of operator means. The latter are extremely useful in the theory of electrical networks, see e.g. Anderson and Trapp [7]. Other recent papers on operator means and operator monotone functions include [131] and [156]. Operator inequalities are an active area of research with many contributions by Ando, Furuta [105], Hansen and Pedersen [117], Uchiyama [277, 278, 279, 280, 281] and others. A recent monograph is Zhan [297].
Chapter 12
Subordination and Bochner’s functional calculus
In this chapter we consider strongly continuous contraction semigroups of operators on a Banach space. Our focus will be on subordination of such semigroups in the sense of Bochner. We give a proof of Phillips’ theorem describing the infinitesimal generator of the subordinate semigroup and discuss the related functional calculus for generators of semigroups. In the final section of this chapter we discuss the probabilistic counterpart of subordination and use it to obtain eigenvalue estimates for subordinate processes.
12.1
Semigroups and subordination in the sense of Bochner
In this section we will briefly discuss a method to generate new semigroups from a given one. We assume that the reader is familiar with the theory of semigroups on a Banach space .B; k k/; our standard references are the monographs by Davies [72], Pazy [230] and Yosida [296]. Throughout this section .B; kk/ denotes a Banach space, .B ; kk / its topological dual and hu; i stands for the dual pairing between u 2 B and 2 B . Recall that a strongly continuous or C0 -semigroup of operators on B is a family of bounded linear operators T t W B ! B, t > 0, which is strongly continuous (at t D 0), i.e. lim kT t u
t !0
uk D 0
for all u 2 B;
and has the semigroup property T t Ts D Ts T t D T tCs ;
for all s; t > 0:
If kT t uk 6 kuk for all u 2 B and t > 0, we call .T t / t >0 a C0 -contraction semigroup. The (infinitesimal) generator of the semigroup is the operator Tt u u Au WD strong- lim ; t !0 t ³ ² Tt u u exists as strong limit : D.A/ WD u 2 B W lim t !0 t
(12.1)
12.1 Semigroups and subordination in the sense of Bochner
131
Since A is the (strong) right derivative of T t at zero, and since .T t / t >0 is a semigroup, we have Z t Z t Tt u u D Ts Au ds D ATs u ds; u 2 D.A/; t > 0: (12.2) 0
0
This shows, in particular, the following elementary but useful inequality ® ¯ kT t u uk 6 min t kAuk; 2kuk ; u 2 D.A/; t > 0:
(12.3)
The generator .A; D.A// of a C0 -contraction semigroup is a densely defined linear operator which is dissipative and closed. Dissipative means that one of the following equivalent conditions is satisfied Re hAu; i 6 0
for all u 2 D.A/; 2 F .u/
(12.4)
where F .u/ D ¹ 2 B W kk2 D kuk2 D hu; iº, ku
Auk > kuk for all u 2 D.A/; > 0;
(12.5)
ku
Auk > Re kuk for all u 2 D.A/; 2 C; Re > 0:
(12.6)
Generators are, in general, unbounded operators. By the Hille–Yosida theorem an operator A generates a C0 -contraction semigroup if, and only if, D.A/ is dense in B, A is dissipative and the range . A/.D.A// D B for some (hence, all) > 0. The resolvent set %A of a closed operator A consists of all 2 C such that the operator A WD id A has a bounded inverse denoted by R WD . A/ 1 ; the family .R /2%A is the resolvent of A. It is well known that %A is open and that for C0 -contraction semigroups ¹Re > 0º %A ; in particular, .0; 1/ %A . The set A WD C n %A is called the spectrum of A. The resolvent operators satisfy the resolvent estimate kR uk 6
1 kuk
for all u 2 B; > 0;
(12.7)
and the following resolvent equation holds for all ; z 2 %A R
Rz D .z
/ Rz R :
(12.8)
This follows exactly as in the Hilbert space setting, cf. page 110, and one sees immediately that 7! hR u; i is analytic for all u 2 B and 2 B . There is a one-to-one correspondence between a C0 -contraction semigroup .T t / t >0 and its generator .A; D.A// which can formally be expressed by writing T t D e tA . If A is bounded, the exponential e tA may be defined by the exponential series; in the general case one has to use the Yosida approximation, A WD AR , > 0. By the resolvent estimate (12.7) kA uk D kAR uk D kR u
uk 6 2 kuk
132
12 Subordination and Bochner’s functional calculus
which shows that A is bounded. Therefore, exp.tA / can be defined as an exponential series and one can show that T t u D strong- lim e tA u: !1
In this sense, we may indeed write T t D e tA . The following method to generate a new C0 -semigroup from a given one is due to S. Bochner. It uses vaguely continuous convolution semigroups introduced in Definition 5.1 and Bernstein functions which appear as Laplace exponents, cf. Theorem 5.2. Proposition 12.1. Let .T t / t>0 be a C0 -contraction semigroup on the Banach space B and let . t / t>0 be a vaguely continuous convolution semigroup of sub-probability measures on Œ0; 1/ with corresponding Bernstein function f . Then the Bochner integral Z f
T t u WD
Ts u t .ds/;
t > 0;
(12.9)
Œ0;1/
defines again a C0 -contraction semigroup on the Banach space B. Proof. Since t 7! T t u is strongly continuous, and since
Z
Z Z
T u .ds/ kT uk .ds/ 6 6 s t s t
Œ0;1/
Œ0;1/
Œ0;1/
kuk t .ds/ 6 kuk; f
the operators (12.9) are well defined and contractive. In particular, every T t , t > 0, is a bounded linear operator and we find, using the semigroup property of .T t / t >0 , for all s; t > 0 Z f f Tsf Tr u t .dr/ Ts T t u D Œ0;1/
Z D
Z T Tr u s .d/ t .dr/ Œ0;1/
Z D
Œ0;1/
Z TCr u s .d/ t .dr/ Œ0;1/
Œ0;1/
Z D
T u s ? t .d/: Œ0;1/ f
f
Since . t / t >0 is a convolution semigroup, this proves that Ts T t
f
D TsCt . The
f
strong continuity of .T t / t >0 finally follows from Z
f
T u u 6 kTs u uk t .ds/ C 1 t Œ0;1/
t Œ0; 1/ kuk
which tends to zero as t ! 0 since vague- lim t !0 t D ı0 and lim t!0 t Œ0; 1/ D 1, see the discussion following Definition 5.1.
12.1 Semigroups and subordination in the sense of Bochner
133
Definition 12.2. Let .T t / t >0 be a C0 -contraction semigroup on the Banach space B and let . t / t >0 be a vaguely continuous convolution semigroup of sub-probability measures on Œ0; 1/ with corresponding Bernstein function f . Then the semigroup f .T t / t>0 defined by (12.9) is called subordinate (in the sense of Bochner) to the semigroup .T t / t>0 with respect to the Bernstein function f . f The infinitesimal generator of .T t / t>0 will be denoted by .Af ; D.Af //; it is called the subordinate generator. From now on, we will indicate all operators related to the subordinate semigroup f .T t / t>0 by the superscript f . Subordination of subordinate semigroups corresponds to the composition of Bernstein functions. Lemma 12.3. Let .T t / t >0 be a C0 -contraction semigroup on the Banach space B and let . t / t >0 and . t / t >0 be vaguely continuous convolution semigroups of subprobability measures on Œ0; 1/ with corresponding Bernstein functions f and g. Then f ıg .T tg /f u D T t u; t > 0; u 2 B: Proof. From Theorem 5.19 we know that the sub-probability measures t given by R the vague integral Œ0;1/ s t .ds/ form a vaguely continuous convolution semigroup with corresponding Bernstein function f ı g. Therefore, Z Z g f Tr u s .dr/ t .ds/ .T t / u D Œ0;1/
Œ0;1/
Z
Z D
s .dr/ t .ds/
Tr u Œ0;1/
Œ0;1/
Z D
f ıg
Œ0;1/
Tr u t .dr/ D T t
u:
Remark 12.4. It is instructive to consider Bochner’s subordination in the context of the spectral calculus of a dissipative operator .A; D.A// on the R Hilbert space H. We denote by E.d/ the spectral resolution of A and by T t u D . 1;0 e t E.d/u the C0 -semigroup generated by A, cf. Example 11.5. Let f 2 BF and let . t / t >0 be the convolution semigroup associated with it. Then we find Z Z f Tt u D e s E.d/u t .ds/ Œ0;1/
Z D
. 1;0
Z . 1;0
Z D
e . 1;0
e s t .ds/ E.d/u Œ0;1/ tf . /
E.d/u D e
tf . A/
u:
134
12 Subordination and Bochner’s functional calculus
This implies that .Af ; D.Af // coincides with the operator . f . A/; D.f . A/// and that Z f A u D f . A/u D au C bAu C .T t u u/ .dt/; .0;1/
as we have seen in Example 11.6. The formula for Af from Remark 12.4 remains valid in Banach spaces. This result is due to R. S. Phillips [235, Theorem 4.3]. As usual, we set .A0 ; D.A0 // D .id; B/, Ak WD A ı A ı ı A (k times), and ® D.Ak / WD u 2 D.Ak
1
/ W Ak
1
¯ u 2 D.A/ :
With this definition .Ak ; D.Ak // is a closed operator if .A; D.A// is a closed operator. Proposition 12.5. Let .T t / t >0 be a C0 -contraction semigroup on the Banach space B with generator .A; D.A// and let f be a Bernstein function. Then for all k 2 N the set D.Ak / is an operator core for the subordinate generator .Af ; D.Af //. Proof. It is well known that a dense subset D D.Af / is an operator core for the f generator Af if it is invariant under the semigroup, i.e. if T t D D, see e.g. Davies f [72, Theorem 1.9]. Let us show that T t .D.Ak // D.Ak / for all k 2 N. Note that for all u 2 D.Ak / Z
Z
strong- lim
n!1 Œ0;n/
Ts u t .ds/ D
f
Œ0;1/
Ts u t .ds/ D T t u;
u 2 D.Ak /:
Since .A; D.A//, hence .Ak ; D.Ak //, is a closed operator, we find for all m; n 2 N with m < n and all u 2 D.Ak /
Z
k
A
Z
k
Ts A u t .ds/ Ts u t .ds/ D
Œm;n/ Œm;n/ Z 6 kTs Ak uk t .ds/ Œm;n/
Z 6 Œm;n/
which shows that .Ak The closedness of
kTs k t .ds/ kAk uk;
k Œ0;n/ Ts u t .ds//n2N is for all u 2 D.A / a Cauchy sequence. f Ak now shows that T t u 2 D.Ak / for all u 2 D.Ak /.
R
135
12.1 Semigroups and subordination in the sense of Bochner
Theorem 12.6 (Phillips). Let .T t / t >0 be a C0 -contraction semigroup on the Banach space B with generator .A; D.A// and let f be a Bernstein function with Lévy triplet f .a; b; /. Denote by .T t / t >0 and .Af ; D.Af // the subordinate semigroup and its infinitesimal generator. Then D.A/ is an operator core for .Af ; D.Af // and Af jD.A/ is given by Z f A u D au C bAu C .Ts u u/ .ds/; u 2 D.A/: (12.10) .0;1/
The integral is understood as a Bochner integral. Proof. That D.A/ is an operator core of Af follows from Proposition 12.5. Using (12.3) we see that the integral term in formula (12.10) converges for all u 2 D.A/, Z Z Z kTs u uk .ds/ C kTs u uk .dt/ kTs u uk .ds/ D .0;1/
.0;1/
Œ1;1/
Z 6 .0;1/
s .ds/ kAuk C 2Œ1; 1/ kuk;
which means that the operator given by (12.10) is defined on D.A/. Assume first that f .0C/ D 0 and that .T t / t>0 satisfies kT t uk 6 e t > 0 and some > 0. We write f 2 BF with f .0C/ D 0 as Z f ./ D b C .1 e s / .ds/;
t kuk
for all
.0;1/
and denote the corresponding vaguely continuous convolution semigroup of probabilR ity measures by . t / t >0 . By definition, e tf ./ D Œ0;1/ e s t .ds/, and we see that 1 Z 1 e n f ./ n!1 s fn ./ WD .1 e / n1=n .ds/ D ! f ./ 1 Œ0;1/
n
defines a sequence of Bernstein functions fn 2 BF approximating f 2 BF. Obviously, the Lévy triplet of fn is .0; 0; n1=n / and we see from Corollary 3.8 that vague- lim n1=n D ;
(12.11)
0 D lim lim inf n1=n ŒC; 1/; C !1 n!1 Z b D lim lim inf s n1=n .ds/:
(12.12)
n!1
c!0 n!1
(12.13)
Œ0;c/
Throughout the proof we assume, for simplicity, that c and C are always continuity points of the measure and that the limits in c and C are taken along sequences of
136
12 Subordination and Bochner’s functional calculus
continuity points of . The proof of Corollary 3.8 shows that we may then replace lim infn by limn . Since s 7! Ts u u is strongly continuous, the function s 7! hTs u u; i, u 2 B, 2 B , is continuous and we conclude that for all continuity points 0 < c < C < 1 Z Z lim hTs u u; i n1=n .ds/ D hTs u u; i .ds/: n!1 .c;C /
.c;C /
Because of (12.3) we know that jhTs u
u; ij 6 kTs u
ukkk 6 min¹s kAuk; 2 kukº kk
for all u 2 D.A/ and s > 0. The function 1 ^ s is -integrable, and by dominated convergence we see that for all u 2 D.A/ Z Z lim lim hTs u u; i n1=n .ds/ D hTs u u; i .ds/: (12.14) C !1 n!1 .c;C / c!0
.0;1/
For u 2 D.A/ and all c > 0 we find Z Z .Ts u u/ n1=n .ds/ D Œ0;c/
Tr Au dr n1=n .ds/
Œ0;c/
0
Z D
s
Z
s
Z
.Tr Au Œ0;c/
Au/ dr n1=n .ds/
0
Z C
Œ0;c/
s n1=n .ds/ Au:
R Because of (12.13), Œ0;1/ s n1=n .ds/, n 2 N, is a bounded sequence. Using the strong continuity of the semigroup we find for c 2 .0; 1/
Z
Z s
sup .Tr Au Au/ dr n1=n .ds/
n2N
Œ0;c/
0
Z 6 sup kTr Au
Auk sup
r6c
n2N Œ0;1/
s n1=n .ds/
c!0
!0
which implies that Z strong- lim lim
c!0 n!1 Œ0;c/
Finally, we get Z .Ts u ŒC;1/
.Ts u
u/ n1=n .ds/ D bAu;
u 2 D.A/:
(12.15)
Z u/ n1=n .ds/ D
ŒC;1/
Ts u n1=n .ds/
n1=n ŒC; 1/ u:
137
12.1 Semigroups and subordination in the sense of Bochner
Because of (12.12) the sequence n1=n Œ1; 1/, n 2 N, is bounded. Therefore we get for C > 1
Z
Z
6 sup kTs uk n1=n .ds/ sup T u n .ds/ s 1=n
n2N
n2N ŒC;1/
ŒC;1/
Z e
6 sup
s
n2N ŒC;1/
6e
C
n1=n .ds/kuk
sup n1=n Œ1; 1/
C !1
! 0;
n2N
and we conclude that Z strong- lim
lim
C !1 n!1 ŒC;1/
.Ts u
u/ n1=n .ds/ D 0;
u 2 D.A/:
(12.16)
If we combine (12.14)–(12.16) we find that for all u 2 D.A/ and 2 B Z ˝ ˛ f .Ts u u/ .ds/; hAf u; i D lim n.T1=n u u/; D bAu C n!1
.0;1/
holds, and this implies (12.10). If f .0C/ D 0 and if .T t / t >0 is a general C0 -contraction semigroup on B, then for any > 0, TIt WD e t T t is a C0 -contraction semigroup which satisfies the additional assumption used above. It is not hard to check that the generator of this semigroup is .A ; D.A//. From the first part of the proof we know that Z f .e s Ts u u/ .ds/; u 2 D.A/: .A / u D b.A /u C .0;1/
Note that the expression on the right-hand side still makes sense if D 0. For u 2 D.A/ we have
Z
f bAu C .T u u/ .ds/ .A / u
s
.0;1/
Z
s
D bu C .Ts u e Ts u/ .ds/
.0;1/
Z 6 b kuk C
.1 .0;1/
and this converges to 0 as ! 0. This means that Z strong- lim .A /f u D bAu C .Ts u !0
.0;1/
e
s
/ .ds/ kuk
u/ .ds/;
u 2 D.A/:
138
12 Subordination and Bochner’s functional calculus
On the other hand,
f f
T1=n u u TI1=n u
1 1
n n
f
f u T1=n u TI1=n u
D
1
n
Z
s
D .Ts u e Ts u/ n1=n .ds/
Œ0;1/
Z .1
6
e
Œ0;1/
D
1
s
/ n1=n .ds/ kuk
1 n f ./
e 1 n
kuk
n!1
! f ./ kuk
!0
! 0:
This shows that Af u D strong- lim!0 .A /f u and that Af is, on D.A/, given by (12.10). Finally consider h 2 BF with h.0C/ D a > 0. We write h D f C a where f 2 BF and f .0C/ D 0. As above we denote by . t / t >0 the convolution semigroup corresponding to f ; then at WD e ta t , t > 0, is the vaguely continuous convolution semigroup associated with h. Indeed, L at D e ta L t D e ta e tf . Therefore, Z f T th u D Ts u at .ds/ D e ta T t u; u 2 B; t > 0; Œ0;1/
and thus Ah D Af
a id. This completes the proof of the theorem.
Corollary 12.7. Let .A; D.A// be the generator of a C0 -contraction semigroup on B and let f be a Bernstein function. Then D.Af / D D.A/ if, and only if, A is a bounded operator or if b D lim!1 f ./= > 0. If f is a bounded Bernstein function or if A is a bounded operator, the subordinate generator Af is bounded, i.e. D.Af / D B. Proof. Using (12.3) we can estimate the integral term in Phillips’ formula (12.10) in the following way:
Z
Z Z
.Ts u u/ .ds/ 6 kTs u uk .ds/ C kTs u uk .dt/
.0;/
.0;1/
Œ;1/
Z 6 .0;/
s .ds/ kAuk C 2Œ; 1/ kuk:
Therefore we get kAf uk 6 .a C d /kuk C .b C c /kAuk; u 2 D.A/; R where a; b > 0 are from (12.10), c D .0;/ s .ds/ and d D 2Œ; 1/.
(12.17)
139
12.1 Semigroups and subordination in the sense of Bochner
Assume that D.A/ D D.Af / and that b D 0. Since .Af ; D.A// and .A; D.A// are closed operators we have by a theorem of Hörmander, see [296, Chapter II.6, Theorem 2], kAuk 6 c kAf uk C kuk ; u 2 D.A/; with a suitable constant c > 0. Choosing in (12.17) so small that c < 1=.2c/, we obtain 1 kAuk 6 c kAf uk C kuk 6 kAuk C c .d C a/ kuk; 2
u 2 D.A/;
which shows that the operator A is bounded. Conversely, if A is bounded D.A/ D B and by (12.17) Af is bounded, therefore D.Af / D B, too. If b > 0, we get from (12.10) using the estimate leading to (12.17) kAf uk > .b Pick > 0 such that b
c / kAuk
.a C d / kuk;
u 2 D.A/:
c > 0 and observe that then
kAuk 6 c kAf uk C c 0 kuk;
u 2 D.A/;
holds for some constants c; c 0 > 0. Since .A; D.A// is closed, this immediately implies the closedness of the operator .Af ; D.A//. The second part of the assertion follows from (12.17) with D 1, if A is bounded, and with D 0 if f is bounded; in the latter case we used b D 0 and that is a finite measure, cf. Corollary 3.7(v). Corollary 12.8. Let f 2 BF and let .T t / t >0 be a C0 -contraction semigroup on B with generator .A; D.A//. Then the following estimate holds 2e kAf uk 6 f kuk e 1
1 kAuk ; 2 kuk
u 2 D.A/; u ¤ 0:
(12.18)
For the fractional powers . A/˛ , ˛ 2 .0; 1/, one has k. A/˛ uk 6 4 kAuk˛ kuk1
˛
;
u 2 D.A/:
Proof. By Phillips’ theorem, Theorem 12.6, we have Z f A u D au C bAu C .T t u u/ .dt/; .0;1/
u 2 D.A/:
If we combine the elementary convexity estimate min¹1; ctº 6
e e
1
.1
e
ct
/;
c; t > 0;
(12.19)
140
12 Subordination and Bochner’s functional calculus
with the operator inequality (12.3), ² ³ kAuk kT t u uk 6 min t ;2 ; kuk kuk
u 2 D.A/; u ¤ 0; t > 0;
we find for c D kAuk=.2 kuk/ and u ¤ 0 Z kAf uk kAuk kT t u uk 6aCb C .dt/ kuk kuk kuk .0;1/ ² ³ Z kAuk kAuk C min t ; 2 .dt/ 6aCb kuk kuk .0;1/ Z 2e kAuk t kAuk C 1 exp .dt/ 6aCb kuk e 1 .0;1/ 2 kuk 1 kAuk 2e 6 f : e 1 2 kuk Note that 2e=.e (12.19).
1/ 6 4; if we take f ./ D ˛ , ˛ 2 .0; 1/, (12.18) becomes
Corollary 12.9. Let f 2 BF and let .T tA / t>0 , .T tB / t >0 be C0 -contraction semigroups on B with generators .A; D.A// and .B; D.B//, respectively. Assume that the operators A; B commute. Then the following estimate holds for u 2 D.A/ \ D.B/, u ¤ 0, 2e 1 kAu Buk kAf u B f uk 6 ' (12.20) kuk e 1 2 kuk where './ D f ./
f .0/.
Proof. By Phillips’ formula (12.10) we see for u 2 D.A/ \ D.B/ Z Af u B f u D b.A B/u C .T tA u T tB u/ .dt/: .0;1/
From the theory of operator semigroups, see e.g. [230, Chapter I, Theorem 2.6, p. 6], we know that Z t Z t d B A A B .T t s Ts /u ds D T tB s .B A/TsA u ds: Tt u Tt u D 0 0 ds Since B and A commute, so do the semigroups generated by them, and we find Z t kT tA u T tB uk 6 kT tB s TsA .B A/uk ds 6 t k.B A/uk 0
on D.A/ \ D.B/. On the other hand, we have always kT tA u T tB uk 6 2 kuk. From now onwards we can argue exactly as in the proof of Corollary 12.8.
12.1 Semigroups and subordination in the sense of Bochner
141
Without proof we state the following result on the spectrum of a subordinate generator. It is again from Phillips [235, Theorem 4.4]. Theorem 12.10. Let .T t / t >0 be a C0 -contraction semigroup on the Banach space B with generator .A; D.A// and let f be a Bernstein function. Then Af f . A /. The following improvement of Theorem 12.10 is due to Hirsch [136, Théorème 16] and [135, pp. 195–196]. The extended spectrum of an operator A on B is the set N A contained in the one-point compactification C [ ¹1º of C such that N A D A if A is densely defined and bounded and N A D A [ ¹1º otherwise. Further, we extend f 2 CBF to C n .0; 1/ [ ¹1º by setting f .0/ WD f .0C/ 2 Œ0; 1/ and
f .1/ WD lim f ./ 2 .0; 1: !1
Theorem 12.11. Let .T t / t >0 be a C0 -contraction semigroup on the Banach space B with generator .A; D.A// and let f be a complete Bernstein function. Then it holds that N Af D f . N A /. Remark 12.12. If .T t / t >0 gives rise to a transition function of a Markov process X D .X t / t >0 , i.e. if u 2 Bb .E/;
T t u.x/ D P t u.x/ D Ex u.X t /;
then Bochner’s subordination has a probabilistic interpretation which parallels the more specialized situation in Remark 5.20(ii). We know from Definition 5.4 and Proposition 5.5 that every f 2 BF defines a convolution semigroup . t / t >0 of sub-probability measures on Œ0; 1/ or, equivalently, a (killed) subordinator b S D .b S t / t >0 . Without loss of generality we can assume that the processes X and b S are defined on the same probability space and that they are independent. It is not difficult to check that the subordinate process f
X t .!/ WD Xb .!/ WD Xb .!/ S S .!/ t
t
is again a Markov process. Because of independence, the associated operator semigroup is given by Z Z f b P t u.x/ D Ex u.Xb /D Ex u.Xs / P0 .S t 2 ds/ D Ps u.x/ t .ds/: S t
Œ0;1/
f
Œ0;1/
f
Since T t D P t , we have T t D P t , and Bochner’s subordination can be interpreted as a stochastic time change with respect to an independent subordinator. An interesting special case is the subordination of Lévy processes.
142
12 Subordination and Bochner’s functional calculus
Example 12.13. A stochastic process .X t / t >0 with values in Rd is called a Lévy process if it has independent and stationary increments and if almost all sample paths t 7! X t .!/ are right-continuous and have left limits. It is well known that the transition function of a Lévy process is characterized by its Fourier transform which is of the form E0 e iX t D e t ./ ; 2 Rd : The characteristic exponent W Rd ! C is continuous and negative definite in the sense of Schoenberg, cf. Chapter 4, in particular (4.7). Every continuous and negative definite function is uniquely determined by its Lévy–Khintchine formula, see (4.8) in Theorem 4.12 Denote by b S D .b S t / t >0 and . t / t >0 the (killed) subordinator and the convolution semigroup given by the Bernstein function f . Because of independence, we see f
Ee
iX t
Z D
Œ0;1/
Ee
iXs
Z t .ds/ D
e
s ./
Œ0;1/
t .ds/ D e
tf . .//
:
A calculation similar to the one in the proof of Theorem 5.19 shows that f ı is again given by a Lévy–Khintchine formula. This means that f ı is a continuous and negative definite function and that a subordinate Lévy process is still a Lévy process. There is an interesting converse to the last remark of Example 12.13. This is due to Schoenberg [255]; we follow Bochner’s presentation [50, p. 99]. Theorem 12.14 (Schoenberg; Bochner). A function f W .0; 1/ ! Œ0; 1/ is a Bernstein function if, and only if, for all d 2 N the function 7! f .jj2 /, 2 Rd , is continuous and negative definite. Proof. Since 7! jj2 is continuous and negative definite in all dimensions, sufficiency follows from Example 12.13. Conversely, fix d 2 N and assume that f .jj2 / is continuous and negative definite. By Proposition 4.4 this is equivalent to saying that F t .jj2 / WD exp. tf .jj2 // is continuous and positive definite for all t > 0, and by Bochner’s theorem, Theorem 4.11, we know that F t .jj2 / is for fixed t > 0 a Fourier transform. This means that 2
F t .jj / D
Z Rd
e iy dt .dy/;
t > 0;
(12.21)
with a measure dt on Rd which is invariant under rotations and whose total mass dt .Rd / D F t .0/ D exp. tf .0// does not depend on the dimension d . Write !d for the canonical surface measure on the unit sphere S d 1 in Rd and j!d j for the surface volume of S d 1 . Set G t ./ WD F t .jj2 / and note that G t .jj/ D
143
12.1 Semigroups and subordination in the sense of Bochner
G t ./ for all 2 S d
1.
Therefore, we can radialise the integral in (12.21) to get Z 1 F t .jj2 / D G t ./ D G t .jj/ !d .d/ j!d j jjD1 Z Z 1 e i jjy dt .dy/ !d .d/ D j!d j jjD1 Rd Z Z 1 D e i jjy !d .d/ dt .dy/ Rd j!d j jjD1 Z D H 1 .d 2/ .jj jyj/ dt .dy/: 2
Rd
The function H appearing in the last line is essentially a Bessel function of the first kind, see e.g. Stein and Weiss [265, p. 154], H .x/ D c J .x/ x
;
(12.22)
where the constant c D limx!0 J .x/x D 2 . C 1/ is chosen in such a way that H .0/ D 1, cf. [111, 8.440]. Therefore, H .x/ D
1 X
. 1/j
j D0
. C 1/ .x=2/2j : .j C C 1/ jŠ
Let D .d / D .d 2/=2 and let td be the image measure of dt under the map ˆd W y 7! jyj2 =.4/. Then Z Z p p t H 1 .d 2/ .jj jyj/ d .dy/ D H .2 jj r/ td .dr/ Rd
2
Œ0;1/
and td Œ0; 1/ D dt .ˆd 1 Œ0; 1// D dt .Rd / D F t .0/ is independent of d . This shows that for fixed t > 0 the measures .td /d 2N are vaguely bounded and by Theorem A.5 vaguely compact. Consequently, there are a subsequence .dk /k>1 and a measure t such that vague- limk!1 td.k/ D t . Since all measures d.k/ have the same mass, we get from Theorem A.4 that weak- lim tdk D t k!1
and
t Œ0; 1/ D F t .0/:
Without loss of generality we may assume that the whole sequence converges. Then Z p p H .2 jj r/ td .dr/ Œ0;1/
Z D
e Œ0;1/
jj2 r
td .dr/
Z C
Œ0;1/
p p H .2 jj r/
e
jj2 r
td .dr/:
144
12 Subordination and Bochner’s functional calculus
From Lemma 12.15 below we see that the integrand of the second integral converges uniformly to 0 as d ! 1, hence ! 1, while td .0; 1/ is independent of d . Since td converges weakly to t we get Z lim
d !1 Œ0;1/
p p H .2 jj r/ td .dr/ D
Z e
jj2 r
t .dr/
Œ0;1/
R which shows that F t ./ D .0;1/ e r t .dr/, i.e. F t ./ is completely monotone for all t > 0. Since by our construction F t ./ D e tf ./ , we can use Theorem 3.6 to conclude that f is a Bernstein function. Lemma 12.15. (i) There exists a positive constant C > 0 such that for all > 1 and all r > 0, p ˇ ˇ ˇH .2 2 r/ˇ 6 C : (12.23) r (ii) lim!1
p H .2 r/ e r2
r2
D 0 locally uniformly in r.
p (iii) lim!1 supr>0 jH .2 r/
e
r2 j
D 0.
Proof. (i) By (12.22) and [111, 8.411.9] the following integral formula is valid H .y/ D
2 . C 1/ C 12 21
1
Z
.1
t 2 /
1=2
cos yt dt;
y > 0:
(12.24)
0
The second mean value theorem for integrals, cf. e.g. [254, Theorem E.22], shows that there exists 2 Œ0; 1 such that ˇZ 1 ˇ ˇ .1 ˇ
t 2 /
0
1=2
ˇ ˇ ˇˇZ ˇ 1 ˇ ˇ ˇ cos yt dt ˇˇ D ˇ cos yt dt ˇ 6 ; ˇ 0 ˇ y
implying that jH .y/j 6
2 . C 1/ 1 : C 12 21 y
Hence, for r > 0, ˇ p ˇ . C 1/ ˇ H 2 r ˇ 6 1 p p : r C 12 Since lim!1
.C1/ p .C 12 /
D 1, see [111, 8.328.2], we get (12.23).
12.2 A functional calculus for generators of semigroups
145
(ii) We have p jH .2 r/
e
r2
ˇ ˇX ˇ1 j D ˇˇ . 1/j ˇj D1
!ˇˇ r 2j ˇˇ . C 1/ j r 2j . C 1 C j / j Š j Š ˇˇ ! 1 X r 2j . C 1/ j 6 1 . C 1 C j / j Š j D1 ! 1 X . C 1/ j C1 r 2j 2 6r 1 : . C 2 C j / .j C 1/Š j D0
j C1
is positive and converges to zero as ! 1, the claim follows Since 1 .C1/ .C2Cj / from the dominated convergence theorem. 2 (iii) Fix A > 1. Because of (i) and the elementary inequality e r 6 e=r 2 we get ˇ ˇ ˇC p p e ˇˇ r2 r2 ˇ sup jH .2 r/ e j 6 sup jH .2 r/ e j C sup ˇ C 2 ˇ : r r>0 r>A r r2Œ0;A
By (ii) the first term tends to zero as ! 1. Letting A ! 1 proves the claim.
12.2
A functional calculus for generators of semigroups
We continue our study of C0 -contraction semigroups .T t / t >0 on a Banach space B. In this section we will develop a functional calculus for the generators .Af ; D.Af //, f f 2 BF, of the subordinate semigroup .T t / t>0 . This calculus is a natural extension of the spectral calculus in Hilbert spaces, and in many cases it is possible to interpret the subordinate generator Af as the operator f . A/. In Hilbert spaces and for selfadjoint semigroups this follows immediately from the familiar spectral calculus for self-adjoint operators, see Examples 11.5, 11.6 and 11.7. In Banach spaces, one can use the Dunford–Riesz functional calculus to express Af as an unbounded Cauchy integral and to identify this operator with f . A/, see [26, 241] and [251, 252]. The particularly interesting case of fractional powers of dissipative operators is included in this calculus if we take the (complete) Bernstein functions f˛ ./ D ˛ , ˛ 2 .0; 1/. Phillips’ formula (12.10) reads Z 1 ˛ ˛ f˛ . A/ u D A u D .T t u u/ t ˛ 1 dt; u 2 D.A/; (12.25) .1 ˛/ 0 and, if we use the Stieltjes representation (6.5) of f˛ ./, we get from Corollary 12.21 below Balakrishnan’s famous formula for the fractional power of a dissipative operator Z sin.˛/ 1 . A/˛ u D Af˛ u D (12.26) AR t u t ˛ 1 dt; u 2 D.A/: 0
146
12 Subordination and Bochner’s functional calculus
The main result for the functional calculus, Theorem 12.22, shows that Af˛ Afˇ D
Af˛Cˇ ;
that is
. A/˛ . A/ˇ D . A/˛Cˇ ;
holds on D.A/ for ˛; ˇ > 0 such that ˛ C ˇ 6 1; Corollary 12.27 extends this to all ˛; ˇ > 0. We begin with a few preparations. Lemma 12.16. Let f be a Bernstein function, gk ./ WD k.k C / 1 , k 2 N, and set fk WD gk ı f . Then fk 2 BF and fk k D D L k f kCf for a sub-probability measure k on Œ0; 1/ such that k
k!1
! ı0 weakly.
Proof. Since gk ; f 2 BF, the composition fk D gk ı f is in BF. Moreover, kf
fk k kCf D D f f kCf which is in CM since it is the composition of the completely monotone function 7! k.k C / 1 with f 2 BF, cf. Theorem 3.6(ii). Therefore, there exists a measure k on Œ0; 1/ with L k D fk =f . By monotone convergence, fk ./ k k D lim D 6 1: k C f .0C/ !0 f ./ !0 k C f ./
k Œ0; 1/ D lim L .k I / D lim !0
Weak convergence follows from limk!1 fk ./=f ./ D 1 and Lemma A.9. Denote by . t / t >0 the convolution semigroup of measures on Œ0; 1/ associated with the Bernstein function f , and write Z 1 Uk D e kt t dt; k 2 N; (12.27) 0
for the k-potential measure, cf. (5.13). Lemma 12.17. Let fk ; f and k be as in Lemma 12.16 and let .T t / t >0 be a C0 -contraction semigroup on B with generator .A; D.A// and resolvent .R />0 . Then Z Ik u WD Ts u k .ds/; k 2 N; u 2 B; Œ0;1/
defines a family of bounded operators on B and f
Ik D kRk ; f
k 2 N;
where Rk are the subordinate resolvent operators. In particular, we have for all u 2 B that strong- limk!1 Ik u D u and Ik u 2 D.Af /.
147
12.2 A functional calculus for generators of semigroups
Proof. Observe that (5.12) with f replaced by k C f shows L Uk D
1 : kCf
Thus, L .kUk / D k.k C f / 1 D L k , and we conclude that kUk D k . Since t 7! T t u is strongly continuous, this proves for all u 2 B Z Ik u D
1Z
Z Œ0;1/
Ts u k .ds/ D k
kt
Ts u e 1
Z
t .ds/ dt
Œ0;1/
0
Dk
e
kt
0
f
T t u dt
f
D kRk u: Using k
R1 0
e
kt
dt D 1 we find 1
Z kIk u
uk 6
ke
kt
0
f kT t
1
Z uk dt D
u
e 0
s
f
kTs=k u
uk ds: k!1
Because of the strong continuity of the subordinate semigroup we get Ik u ! u in the strong sense, and a similar calculation proves that kIk k 6 1. That Ik u 2 D.Af / f follows from the mapping properties of the resolvent Rk . Proposition 12.18. Let fk ; f 2 BF be as in Lemma 12.16, let Ik be the operator from Lemma 12.17 and denote by Afk and Af the corresponding subordinate generators f and by .R />0 the resolvent of Af . Then Afk is a bounded operator, f
Afk u D Af Ik D kAf Rk u; f
D Ik Af D kRk Af u;
k 2 N; u 2 B;
(12.28)
k 2 N; u 2 D.Af /;
(12.29)
and u 2 D.Af / if, and only if, .Afk u/k2N converges strongly; in that case, Af u D limk!1 Afk u. Moreover, I` Afk D Afk I`
and
Afk I` u D Af` Ik u;
k; ` 2 N; u 2 B:
(12.30)
Proof. The boundedness of Afk follows from the boundedness of the function fk and Corollary 12.7. By Lemma 12.16 fk ./ D
kf ./ Dk 1 k C f ./
L .k I / D ak C
Z .1 .0;1/
e
s
/ kk .ds/
148
12 Subordination and Bochner’s functional calculus
with ak D k.1 k Œ0; 1//. A combination of Phillips’ theorem, Theorem 12.6, for fk and Lemma 12.17 gives for u 2 D.A/ Z Afk u D ak u C .Ts u u/ kk .ds/ .0;1/ (12.31) D
ku C kIk u D
f
f
ku C k 2 Rk u D kAf Rk u:
Since the left and right-hand sides define bounded operators, this equality extends f to all u 2 B, and (12.28) follows. Using the commutativity of the operators Rk k!1
f
and Af on D.Af /, we get (12.29). By Lemma 12.17, kRk u ! u strongly. f f f k If u 2 D.A /, (12.29) shows that limk!1 A u D A u strongly. Conversely, if limk!1 Afk u converges in the strong sense, (12.28) and the closedness of the operator Af prove that u 2 D.Af /. f For (12.30) we use I` D `R` and (12.28) to get f
f
Afk I` D `kAf R` Rk D Af` Ik where the second equality follows from the symmetric roles of k and ` in the middle f f term. Since Af , R` and Rk commute, we also get Afk I` D I` Afk . Corollary 12.19. Let .T t / t >0 be a C0 -contraction semigroup on B with resolvent .R />0 and generator .A; D.A//. For every Bernstein function f it holds that ² ³ f fk D.A / D u 2 B W lim A u exists strongly k!1
² Z D u 2 B W lim
k!1 .0;1/
² D u 2 B W lim .kIk u k!1
.T t u
³
2
u/ k Uk .dt/ exists strongly
³ ku/ exists strongly ;
f
where fk D kf =.k C f /, Ik D kRk , and Uk is the k-potential measure (12.27) associated with the Bernstein function f . Proof. From Proposition 12.18 we know that u 2 D.Af / if, and only if, the limit limk!1 Afk u exists strongly. Moreover, the k-potential measure Uk is k 1 k and Z fk A u D k 1 kUk Œ0; 1/ u C .Ts u u/ k 2 Uk .ds/: .0;1/
Since Uk Œ0; 1/ D L .Uk I 0C/ D .k C f .0C// 1 , we see kf .0C/ k D k 1 kUk Œ0; 1/ D k 1 k C f .0C/ k C f .0C/
k!1
! f .0C/:
This proves the second characterization of D.Af /; the last one follows immediately from (12.31).
149
12.2 A functional calculus for generators of semigroups
Remark 12.20. A close inspection of the proof of Proposition 12.18 shows that we f can replace the approximating operator Ik D kRk by any other bounded operator Jk which is of the form Z Jk u D Ts u k .ds/; u 2 B; Œ0;1/
where k is a family of (possibly signed) measures on Œ0; 1/ which have uniformly bounded variation and satisfy L k D fk =f where fk 2 BFb with limk!1 fk ./ D f ./. Any such Jk satisfies strong- limk!1 Jk u D u for all u 2 B as well as (12.30), which is all we need for the proofs of Proposition 12.18 and Corollary 12.19. The first assertion follows since .T t / t >0 is strongly continuous and since the k converge weakly to ı0 , the second assertion is immediate from the fact that each T t , t > 0, commutes with A, R and the subordinate analogues. An example of such a situation is given in [253] for f 2 CBF. Let us rewrite Corollary 12.19 for a complete Bernstein function f . In this case R we have f ./ D a C b C .0;1/ .s C / 1 .ds/, with a; b > 0 and the Stieltjes R representation measure on .0; 1/ satisfying .0;1/ .1 C s/ 1 .ds/ < 1, see (6.5); the Lévy measure .dt/ has a density m.t/ which is given by m.t/ D L .s .ds/I t/. Corollary 12.21. Let .T t / t>0 be a C0 -contraction semigroup on B with resolvent .R />0 and generator .A; D.A//, and let f 2 CBF with Stieltjes representation given above. Then ³ ² Z f ARs u .ds/ exists strongly D.A / D u 2 B W lim k!1 .0;k/
and we have for u 2 D.A/ Af u D
Z au C bAu C
.sRs u
u/ .ds/
(12.32)
.0;1/
Z D
au C bAu C
ARs u .ds/:
(12.33)
.0;1/
Proof. Applying Phillips’ formula (12.10) for f 2 CBF we see for u 2 D.A/ Z 1 f A u D au C bAu C .T t u u/ m.t/ dt 0 1Z
Z D
au C bAu C
.T t u 0
Z D
au C bAu C
.0;1/ Z 1
se .0;1/
u/e st
st
T t u dt
0
Z D
au C bAu C
.sRs u .0;1/
u/ .ds/
s .ds/ dt u .ds/
150
12 Subordination and Bochner’s functional calculus
and this proves (12.32), and (12.33) follows as sRs u u D ARs u. In order to justify the interchange of integrals in the calculation above, we use the estimate (12.3) and observe that the iterated integrals are finite for u 2 D.A/: Z Z 1 kT t u uk e st dt s .ds/ .0;1/
0
Z
1
Z
6 .0;1/
Z
® ¯ min tkAuk; 2kuk e
1
Z
se
62 .0;1/
st
dt .ds/kuk C
0
Z D2
Z .0;1/
st
dt s .ds/
Z
Z
0
.ds/ kuk C
Œ1;1/
1
st e Œ1;1/
st
dt .ds/kAuk
0
1 .ds/ kAuk < 1: s
In order to see the assertion for the domain, we use Remark 12.20 with Z fk ./ D .ds/: .0;k/ s C From this it is possible to compute I.z/ D Im Œ.f .z/ fk .z//=f .z/ and an elementary but lengthy calculation shows for z D x C iy 2 H" 1 I.z/ D jfk .z/j
Z
Z t 2.k;1/
s2.0;k/
.t s/y.x 2 C y 2 / .ds/ .dt/: ..t C x/2 C y 2 /..s C x/2 C y 2 /
The integrand is positive since Im z D y > 0. Moreover, by monotone convergence we see R R 1 1 f ./ fk ./ Œk;1/ s .ds/ Œk;1/ sC .ds/ !0C ! 2 Œ0; 1/: D R R 1 1 fk ./ .0;k/ sC .ds/ .0;k/ s .ds/ Therefore, Theorem 6.2(iv) shows that .f fk /=fk is in CBF, and consequently f =fk D 1 C .f fk /=fk 2 CBF, and fk =f 2 S by Theorem 7.3. This proves that fk =f D L k for a sub-probability measure k on Œ0; 1/. The form of D.Af / follows now from Remark 12.20 and Corollary 12.19. We can use the knowledge of the structure of the domain D.Af / to construct a functional calculus for semigroup generators. Theorem 12.22. Let .A; D.A// be the generator of a C0 -semigroup .T t / t >0 on the Banach space B, and let f; g 2 BF. Then we have (i) Acf D cAf for all c > 0; (ii) Af Cg D Af C Ag ;
12.2 A functional calculus for generators of semigroups
151
(iii) Af ıg D .Ag /f ; (iv) AcCid Cf D
c id CA C Af for all c > 0;
(v) if fg 2 BF, then Afg D Af Ag D Ag Af . The equalities in (i)–(v) are identities in the sense of closed operators, including their domains which are the usual domains for sums, compositions etc. of closed operators. Before we proceed with the proof of Theorem 12.22 let us mention the following useful corollaries. Both of them are immediate consequences of Theorem 12.22(v) in conjunction with Proposition 7.10 and Definition 10.1, respectively. Corollary 12.23. Let .A; D.A// be as in Theorem 12.22 and assume that f; g 2 CBF. Then f ˛ g 1 ˛ 2 CBF for all ˛ 2 .0; 1/ and Af
˛g1 ˛
D
˛
Af Ag
1 ˛
D
Ag
1 ˛
˛
Af :
Corollary 12.24. Let .A; D.A// be as in Theorem 12.22 and assume that f; f ? 2 SBF, cf. Definition 10.1, are a conjugate pair, i.e. f ? ./ D =f ./. Then AD
?
Af Af D
?
Af Af :
Proof of Theorem 12.22. For f; g 2 BF we know that cf; f C g; f ı g 2 BF. Since D.A/ D.Af / \ D.Ag /, all of the above operators are densely defined. By the linearity of the definition of .Af ; D.Af //, see Corollary 12.19, (i) and (ii) are immef ıg diate, (iii) is a consequence of the transitivity of the subordination: T t D .T tg /f , see Lemma 12.3. For (iv) we note that Af is A-bounded in the sense that kAf uk 6 ckAuk C c 0 kuk for c; c 0 > 0 and all u 2 D.A/, cf. (12.17). Thus, .c C A C Af ; D.A// is a closed operator, and the assertion follows from Phillips’ formula (12.10). For (v) we assume that fg 2 BF. Write h for any of the Bernstein functions f; g or fg and set, as in Lemma 12.16, hk WD
kh kCh
and
hk D L h;k ; h
k 2 N;
(12.34)
for a suitable sub-probability measure h;k on Œ0; 1/. Note that fk g` L fg;m D .fg/m L f;k L g;` holds for all k; `; m 2 N. By (12.34), k D L kı0 hk D k 1 kCh
kh;k
(12.35)
allows to rewrite the identity (12.35) in terms of convolutions of (signed) measures k`.f;k
ı0 / ? .g;`
ı0 / ? fg;m D
m.fg;m
ı0 / ? f;k ? g;` :
(12.36)
152
12 Subordination and Bochner’s functional calculus
We want to show that f
k`A.fg/m Rk R`g u:
fg uD mAfk Ag` Rm
Applying Phillips’ formula (12.10) to Ahk shows Z hk A u D k 1 h;k Œ0; 1/ u C
.Ts u
(12.37)
u/ kh;k .ds/
.0;1/
Z D
Ts u kh;k .ds/
ku
Œ0;1/
Z Dk
Ts u .h;k
ı0 /.ds/;
Œ0;1/
and from Lemma 12.17 we know that Z h kRk u D
Ts u h;k .ds/: Œ0;1/
Since the operators Ahk and Rkh , where h stands for f; g or fg, are bounded we can freely interchange the order of integration in the calculation below. fg mAfk Ag` Rm u Z D k` Tr u .f;k
Z ı0 /.dr/
Œ0;1/
Z D k`
Z
Z Ts u .g;`
T t u fg;m .dt/ Œ0;1/
Z TrCsCt u .f;k
Œ0;1/
ı0 /.ds/
Œ0;1/
Œ0;1/
ı0 /.dr/ .g;`
ı0 /.ds/ fg;m .dt/
Œ0;1/
Z D k`
Ts u .f;k
ı0 / ? .g;`
ı0 / ? fg;m .ds/:
Œ0;1/
A very similar calculation leads to k`A
.fg/m
f Rk
R`g u
Z D
m
Ts u .fg;m
ı0 / ? f;k ? g;` .ds/
Œ0;1/
and the convolution identity (12.36) shows that (12.37) holds. Since (12.37) is an equality between bounded operators, it extends from D.A/ to all u 2 B. Using (12.37) we can now prove (v). Recall from operator theory that Af Ag is a closed operator on D.Af Ag / D ¹u 2 B W u 2 D.Ag / and Ag u 2 D.Af /º. If u 2 D.Af Ag /, we find by letting ` ! 1, k ! 1 and then m ! 1 in (12.37) that u 2 D.Afg /, see Corollary 12.19. This shows that Afg extends Af Ag . Conversely, if f 2 D.Afg /, see Corollary 12.19, we first let m ! 1 in (12.37) and then ` ! 1 and k ! 1. This proves that u 2 D.Af Ag / and that Af Ag extends Afg . Therefore Af Ag D Afg and, since f and g play symmetric roles, also Ag Af D Afg .
153
12.2 A functional calculus for generators of semigroups
Remark 12.25. The proof of Theorem 12.22(v) shows that the functional calculus is also an operational calculus. In fact, (12.37) is derived from the identity (12.35) between functions from BFb and CMb or from the corresponding identity for (signed) measures (12.36). In the proof of Theorem 12.22 we see that it is sufficient to verify the operator identity at the level of CMb and BFb , i.e. for the trivial semigroup .e t / t >0 rather than the operator semigroup .T t / t>0 . The requirement that fg 2 BF for f; g 2 BF in Theorem 12.22(v) is quite restrictive. We can overcome this difficulty if f; g are complete Bernstein functions by using the log-convexity of CBF, see Proposition 7.10, i.e. f ˛ g1
˛
2 CBF
for all f; g 2 CBF; ˛ 2 .0; 1/:
(12.38)
This, together with Theorem 12.22 enables us to write down a consistent formula for the operator .fg/. A/ and all f; g 2 CBF—even if Afg has no longer any meaning since it is not the generator of a subordinate semigroup if fg 62 BF. Definition 12.26. For f1 ; f2 ; : : : ; fn 2 CBF, n 2 N, we set 1=n 1=n 1=n n .f1 f2 : : : fn /. A/ D . Af1 /. Af2 / . Afn /
(12.39)
on the natural domain for compositions of closed operators. Let A D ¹f1 f2 : : :fn W n 2 N; fj 2 CBF; 0 6 j 6 nº denote the set of all finite products of complete Bernstein functions. We want to show that the above definition extends Theorem 12.22(v) to the set A. First, however, we have to check that (12.39) is independent of the representation of F 2 A. Assume that F D f1 f2 fn and F D g1 g2 : : : gm , m > n, fj ; gj 2 CBF, are two representations of F . Extending (12.38) to n-fold products we see by Theorem 12.22(v) 1=n 1=n 1=n n 2 1=n 1=n . Af1 /. Af2 / . Afn / D . 1/.n / ŒAF n D Œ AF n ; 2
where we used that . 1/n D . 1/.n / . A similar formula holds for the other representation of F . In particular, F 1=n ; F 1=m 2 CBF and it remains to show that 1=n 1=m Œ AF n D Œ AF m . This, however, follows from 1=m 1=n 1=n Œ AF n D Œ AF n=m D
AF
1=m
;
where the first equality is well known for (arbitrary) powers of closed operators, while the second one comes from Theorem 12.22(iii). Thus, (12.39) is a well defined closed operator for all F 2 A and the following corollary shows that Definition 12.26 extends Theorem 12.22(v).
154
12 Subordination and Bochner’s functional calculus
Corollary 12.27. Let f; g 2 CBF and let .T t / t>0 be a C0 -contraction semigroup on B with generator .A; D.A//. For H D fg 2 A it holds that H. A/ D Af Ag D Ag Af :
(12.40)
More generally, if H D F G with F; G 2 A, then H. A/ D F . A/G. A/ D G. A/F . A/:
(12.41)
The above equalities are identities between closed operators. p
Proof. p Put B D Ap fgp . By definition, H. A/ D B 2 , and by Theorem 12.22(v) p p B D A fg D A f A g D A g A f . Since p p p p p p ¯ ® D.B 2 / D u 2 B W u 2 D.A f g / and A f g u 2 D.A f g / p p p ® D u 2 B W u 2 D.A g /; A g u 2 D.A f /;
A
p f
p
A
g
u 2 D.A
p g
/ and
p
A
g
p
A
f
p
A
g
p
u 2 D.A
f
¯ / ;
we get p
B 2 D .A
f
p
A
g
/.A
p f
p
A
g
p
/ D .A
f
A
p f
/.A
p g
p
A
g
/ D Af Ag D Ag Af :
This proves (12.40). Iterating this identity we get (12.41) first for F 2 CBF and G D g1 g2 : : : gm with gj 2 CBF, and then for F; G 2 A. We continue with a study of the domain D.Af / of the subordinate generator. For this it is important to understand the asymptotic behaviour of kT t u uk for t ! 0 and u 2 D.Af /. Let f 2 BF and write U for the potential measure, i.e. L U D 1=f . Then ˇs WD f .s/.U
ı1=s ? U /;
s > 0;
(12.42)
is a family of (signed) measures and L .ˇs I / D
f .s/ .1 f ./
e
=s
/:
The next lemma is stated for special Bernstein functions f 2 SBF; recall that CBF SBF. Lemma 12.28. Let .ˇs /s>0 be as in (12.42) and assume that f 2 SBF. Then the total variation of the measures ˇs is uniformly bounded by 2.e C 1/.
12.2 A functional calculus for generators of semigroups
155
Proof. We know from Theorem 10.3 that U.dt/ a nonR 1 D c ı0 .dt/ C u.t/ dt with ac increasing density u.t/, t > 0, such that 0 u.t/ dt < 1. Writing ˇs for the absolutely continuous part of ˇs we get cı1=s kT V C kˇsac kT V 6 2cf .s/ C kˇsac kT V
kˇs kT V 6 f .s/kcı0 and 1ˇ
ˇ ˇ ˇ ˇ dˇs .t/ ˇ dt ˇ dt ˇ 0 Z 1=s Z D f .s/ u.t/ dt C
kˇsac kT V D
Z
0
1
u.t
1=s/
u.t/ dt
1=s 1=s
Z D 2f .s/
u.t/ dt 0 1=s
Z 6 2f .s/ e
e
st
u.t/ dt
0
6 2 ef .s/
1 D 2e: f .s/
Since f ./ D 1=L .cı0 .dt/Cu.t/ dtI /, we have sup>0 f ./ D lim!1 f ./ D c 1 , i.e. f is bounded if, and only if, c > 0. This shows that the total variation is bounded by 2 C 2e or by 2e, depending on f being bounded or unbounded. Lemma 12.29. Let f 2 SBF with potential measure U , set fk D kf =.k C f / and let .ˇs /s>0 be as in (12.42). For every C0 -contraction semigroup .T t / t >0 on B with generator .A; D.A// the operators Z T t u ˇs .dt/; u 2 B; Œ0;1/
are uniformly bounded, and the following identity holds Z Z fk f .s/ .T1=s id/ T t u k .dt/ D A T t u ˇs .dt/; Œ0;1/
(12.43)
Œ0;1/
where fk =f D L k as in Lemma 12.16. Proof. The uniform boundedness follows directly from Lemma 12.28, while (12.43) is a consequence of Remark 12.25 and the identity f .s/ .e
=s
1/L .k I / D f .s/ .e
=s
1/
fk ./ f ./
D fk ./ f .s/ L .ı1=s ? U D
fk ./ L .ˇs I /:
U I /
156
12 Subordination and Bochner’s functional calculus
We will now combine Lemma 12.29 with the technique developed in Proposition 12.18 and the proof of Theorem 12.22(v) to derive the next result. Theorem 12.30. Let f 2 SBF, let .ˇs /s>0 be as above and let .T t / t >0 be a C0 contraction semigroup on B with generator .A; D.A//. Then Z f .s/ .T1=s u u/ D Af T t u ˇs .dt/ s > 0; u 2 B; (12.44) Œ0;1/
Z D
T t Af u ˇs .dt/ Œ0;1/
s > 0; u 2 D.Af /:
(12.45)
Proof. Recall that limk!1 Afk v existsRif, and only if, v 2 D.Af /. Therefore, the limit k ! 1 in (12.43) shows that v D Œ0;1/ T t u ˇs .dt/ 2 D.Af / and that (12.44) holds. This implies (12.45) for all u 2 D.Af /, since Af is a closed operator. Corollary 12.31. Let f 2 SBF and let .T t / t >0 be a C0 -contraction semigroup on B with generator .A; D.A//. Then we have kT t u
uk 6
2.e C 1/ f kA uk; f .t 1 /
u 2 D.Af /:
(12.46)
Proof. If u 2 D.Af /, (12.45) gives for t D 1=s, kT t u
uk 6
1 kˇ1=t kT V kAf uk; f .t 1 /
and the assertion follows because sups>0 kˇs kT V 6 2.e C 1/, see Lemma 12.28. The following corollary contains the converse of Corollary 12.7. Corollary 12.32. Let f 2 SBF and let .T t / t >0 be a C0 -contraction semigroup on B with generator .A; D.A//. The subordinate generator Af is bounded if, and only if, A is bounded or f is bounded. Proof. The sufficiency has already been established (under less restrictive assumptions) in Corollary 12.7. In order to see the necessity, let Af be a bounded operator, i.e. kAf uk 6 c kuk for some c > 0 and all u 2 B. Suppose that lim!1 f ./ D 1. By Corollary 12.31, 2.e C 1/ kAf uk 2.e C 1/c kT u uk 6 6 1 kuk f . / kuk f . 1 / for all u 2 B, u ¤ 0. Thus, kT u uk 2.e C 1/c 2.e C 1/c D lim D 0: 6 lim 1 !0 0¤u2B !0 f . / kuk f ./ !1 lim sup
which shows that .T t / t >0 is continuous in the uniform operator topology. This means that the generator A of .T t / t >0 is bounded, cf. [230, p. 2, Theorem 1.2].
12.2 A functional calculus for generators of semigroups
157
Our next corollary is a generalization of the well known relation for fractional powers D.. A/ˇ / D.. A/˛ / if 0 < ˛ 6 ˇ 6 1. Corollary 12.33. Let .T t / t >0 be a C0 -contraction semigroup on B with generator .A; D.A// and let f; g 2 BF with Lévy triplets .a; b; f / and .0; 0; g /. If Z 1 g .dt/ < 1 for some > 0; (12.47) 1/ .t f .0;/ then D.Af / D.Ag /. Proof. If u 2 D.A/ D.Af /, we can use Corollary 12.31 and find for sufficiently small > 0
Z
g g
.T t u u/ .dt/ kA uk D
.0;1/
Z 6 .0;/
Z 6 .0;/
kT t u
g
uk .dt/ C 2
Z Œ;1/
g .dt/ kuk
1 g .dt/ kAf uk C 2g Œ; 1/ kuk: f .t 1 /
Because of our assumption, the integral above converges, and since D.A/ is an operator core for Af and Ag , the inequality extends to all u 2 D.Af /. This shows that u 2 D.Ag /. Remark 12.34. In the notation of Corollary 12.33 it is easy to see that Z 1 e g Œı; / 6 .1 e s=ı / g .ds/ 6 g.ı 1 .1 e / Œı;1/ e 1
1
/
holds for all 0 < ı < . Note that Z Z 1 1 g lim .dt/ D g .dt/; 1 1 ı!0 Œı;/ f .t / .0;/ f .t / whenever the integral on the right-hand side exists. Integrating by parts we get Z Z 1 g Œı; / t 2 f 0 .t 1 / g g .dt/ D C Œt; / dt 1 2 1 f .ı 1 / Œı;/ f .t / Œı;/ f .t / Z g.ı 1 / e t 2 f 0 .t 1 /g.t 1 / dt 6 C e 1 f .ı 1 / f 2 .t 1 / Œı;/ for > 0 and ı 2 .0; /. Therefore, a sufficient condition for (12.47) to hold is that 7!
f 0 ./g./ f 2 ./
158
12 Subordination and Bochner’s functional calculus
is integrable in some neighborhood of C1 and that g./ D O.1/ f ./
as ! 1:
The above remark covers an interesting special case. Since Bernstein functions are non-decreasing and concave, we have 1 f 0 ./ 6 f ./ and both conditions in Remark 12.34 are met if g./=f ./ decays like some power , > 0. Corollary 12.35. Let f; g 2 BF and let .T t / t >0 be a C0 -semigroup on B with generator .A; D.A//. If for some > 0 the ratio g./=f ./ D O . / as ! 1, then D.Af / D.Ag /. The following result shows that the functional calculus is stable under pointwise limits of Bernstein functions. Theorem 12.36. Let .T t / t>0 be a C0 -contraction semigroup on B with generator .A; D.A//. Assume that .f n /n2N is a sequence of Bernstein functions with f ./ D limn!1 f n ./. Then n
strong- lim Af u D Af u; n!1
for all u 2 D.A2 /:
Proof. Assume first that f .0C/ D a > 0 and write fk D kf =.k C f / and fkn D kf n =.kCf n /. Each k=.kCf n / is a completely monotone function which is bounded by 1; therefore, it is the Laplace transform of a sub-probability measure kn and we see fkn kf n k C f k k D C 1 D 1 fk k C f n kf f kCfn k k n D C1 L k C1 : f f Since 1=f D L U 2 CM, cf. (5.12), we see that fkn =fk D L kn with the signed measure kn D .kU C ı0 / kn ? .kU C ı0 /. The total variations of the signed measures . kn /n2N satisfy k sup k kn kT V 6 2 C 1 < 1 for every k 2 N: f .0C/ n2N Now Remark 12.20 applies to the sequence .fkn /n2N and shows that n
strong- lim Afk u D Afk u n!1
for all k 2 N; u 2 D.A/:
159
12.2 A functional calculus for generators of semigroups
Let .an ; b n ; n / denote the Lévy triplet of f n . Recall from the proof of Phillips’ theorem, Theorem 12.6, the estimate Z n kAf uk 6 b n C s n .ds/ kAuk C an C n Œ1; 1/ kuk: .0;1/
Combining this with the elementary convexity inequality min¹1; sº 6 s > 0, we get n
kAf uk 6
2 e f n .1/ .kAuk C kuk/ 6 c .kAuk C kuk/ ; e 1
e e 1
.1
e
s /,
n 2 N; u 2 D.A/;
where c is independent of n 2 N. Because of Proposition 12.18 we have n
Af u
n
fn
n
Afk u D Af u
fn
n
kRk Af u D
n
n
Rk Af Af u
which implies that for all u 2 D.A2 / C 1 n n kAf Af uk 6 kA2 uk C kAuk C kuk : k k
n
n
kAf u
Afk uk 6
The same argument shows that the inequality is valid for kAf u same constant C . Therefore, n
kAf u
n
Af uk 6 kAf u 6
n
n
Afk uk C kAfk u
Afk uk with the
Afk uk C kAfk u
2C n kA2 uk C kAuk C kuk C kAfk u k
Af uk
Afk uk:
n
Letting n ! 1 and then k ! 1 proves that limn!1 Af u D Af u on D.A2 /. If f .0C/ D 0, we replace f and f n in the above calculations by f C and f n C, respectively. Because of Theorem 12.22 n
n
u C Af u D ACf u
n!1
! ACf u D
u C Af u;
u 2 D.A2 /;
and the general case follows. Remark 12.37. It is straightforward to extend the functional calculus to Stieltjes functions. Let .A; D.A// be the generator of a C0 -contraction semigroup .T t / t >0 on B and denote by .R />0 the resolvent. We define the zero-resolvent and the potential operator by Z n
R0 u WD lim R u; !0
and
V u WD lim
n!1 0
T t u dt;
with domains D.R0 / and D.V /, respectively, comprising all u 2 B where the limits above exist in the strong sense. The following facts are well known, see e.g. [29,
160
12 Subordination and Bochner’s functional calculus
Chapter II.11]. The zero-resolvent .R0 ; D.R0 // is an extension of the potential operator .V; D.V // and R0 is densely defined if, and only if, lim!0 R u D 0 for all u 2 B. Moreover, range.R0 / D.A/, and on D.R0 / we have AR0 u D u. Since ³ ² range.A/ D u 2 B W lim R u D 0 ; !0
R0 is densely defined if, and only if, range.A/ is dense in B. If R0 is densely defined we have R0 D A 1 . Assume, therefore, that D.R0 / is dense in B. R For every 2 S given by ./ D a 1 C b C .0;1/ . C t/ 1 .dt/ we define Z . A/u WD aR0 u C bu C
R t u .dt/; .0;1/
u 2 range.A/:
Since for u D Av, v 2 D.A/, it holds that R0 u D R0 Av D we see that . A/u D Af v;
v and R t u D R t Av,
for all u 2 range.A/; u D Av;
where f is the complete Bernstein function given by Z f ./ D a C b C
.0;1/
.dt/: t C
Denote by f ? the conjugate of the complete Bernstein function f , i.e. the unique function f ? 2 CBF such that f ./f ? ./ D . Then we see for all u 2 range.A/ ?
Af Af v D
u D Av D
?
Af . A/u ?
which means that . A/ is the right-inverse of Af on range.A/. ? ? ? ? Now let v D Af w for w 2 D.AAf /. Then u D Av D AAf w D Af Aw and ?
?
. A/Af Aw D Af Af w D
Aw
?
?
which shows that . A/ is the left-inverse of Af on range.A/ \ D.Af /. This proves the following result: Let .A; D.A// be the generator of some C0 -contraction semigroup on B such that range.A/ is dense in B and let f; f ? 2 CBF be conjugate, i.e. f ./f ? ./ D . Then ./ WD f ./= is a Stieltjes function and ?
.Af / 1 u D . A/u
?
for all u 2 range.A/ \ D.Af /:
12.3 Eigenvalue estimates for subordinate processes
12.3
161
Eigenvalue estimates for subordinate processes
For ˛ 2 .0; 2, the generator of a killed symmetric ˛-stable process in an open subset D of Rd is the Dirichlet fractional Laplacian . /˛=2 jD . The spectrum of . /˛=2 jD is very important both in theory and in applications. Although a lot is known in the case ˛ D 2, until recently very little was known for ˛ < 2. In this section we discuss the spectrum of the generator of a general killed subordinate process. The main tools of this section are subordinate killed processes and the theory of Dirichlet forms. Let E be a locally compact separable metric space, B D B.E/ the Borel -algebra on E, and m a positive Radon measure on .E; B/ with full support supp m D E. Let X D .X t ; Px / t >0;x2E be an m-symmetric Hunt process on E. Adjoined to the state space E is a cemetery point @ … E; the process X retires to @ at its lifetime WD inf¹t > 0 W X t D @º. Denote by P t .x; dy/ the transition function of X. The transition semigroup .P t / t >0 and the resolvent .Gˇ /ˇ >0 of X are defined by P t g.x/ WD Ex g.X t / D Ex g.X t /1¹t<º ; "Z Z 1 Z 1 Gˇ g.x/ WD e ˇ t P t g.x/ dt D Ex e ˇ t g.X t / dt D Ex e 0
0
# ˇt
g.X t / dt :
0
Here g is a non-negative Borel measurable function on E and we are using the convention that any function g defined on E is automatically extended to E@ D E [ ¹@º by setting g.@/ D 0. The L2 -generator of .P t / t >0 will be denoted by A and its domain by D.A/, see Appendix A.2 for details. Let .E; D.E// be the Dirichlet form associated with X , i.e. ´ ˝ ˛ E.u; v/ D . A/1=2 u; . A/1=2 v L2 ; (12.48) D.E/ D D.. A/1=2 /: In general, .D.E/; E/ is not a Hilbert space. Therefore, one considers the forms Eˇ .u; v/ WD E.u; v/ C hu; viL2 ;
u; v 2 D.E/; ˇ > 0;
which make .D.E/; Eˇ / into a Hilbert space. Note that cˇ E1 .u; u/ 6 Eˇ .u; u/ 6 Cˇ E1 .u; u/ for suitable constants cˇ ; Cˇ > 0; this means that the spaces .D.E/; Eˇ / coincide. Let .T t / t >0 and .Rˇ /ˇ >0 be the semigroup and resolvent associated with the operator A or, equivalently, the Dirichlet form .E; D.E//. It follows from [102, Theorem 4.2.3] that .T t / t >0 can be identified with .P t / t>0 and that .Rˇ /ˇ >0 can be identified with .Gˇ /ˇ >0 . So in this section, we will use .T t / t >0 , .Rˇ /ˇ >0 and .P t / t >0 , .Gˇ /ˇ >0 interchangeably.
162
12 Subordination and Bochner’s functional calculus
For any open subset D of E, let D D inf¹t > 0 W X t … Dº be the first exit time of X from D. The process X D obtained by killing the process X upon exiting from D is defined by ´ X t ; t < D ; D X t WD @; t > D : The killed process X D is again an m-symmetric Hunt process on D, see [102] or Appendix A.2. The Dirichlet form associated with X D is .ED ; D.ED // where ED D E and ® ¯ D.ED / D u 2 D.E/ W u D 0 E-q.e. on E n D : (12.49) Here E-q.e. stands for quasi everywhere with respect to the capacity associated with the Dirichlet form .E; D.E//. Let .P tD / t >0 and .GˇD /ˇ >0 denote the semigroup and resolvent of X D , and let AD be the L2 -generator of X D . The following result will play an important role in this section. Note that the semigroup version of this result is not true, see [75]. Lemma 12.38. For any ˇ > 0 and every g 2 L2 .E; m/ with g D 0 m-a.e. on E n D, we have hGˇD g; giL2 6 hGˇ g; giL2 : (12.50) Proof. For every ˇ > 0 and every g 2 L2 .E; m/ with g D 0 m-a.e. on E n D, the strong Markov property of X shows Gˇ g.x/ D GˇD g.x/ C HˇD Gˇ g.x/ for all x 2 D: This is the Eˇ -orthogonal decomposition of Gˇ g into GˇD g 2 D.ED / and its orthogonal complement, see (A.20) in Appendix A.2. Here HˇD g.x/ WD Ex e ˇD g.XD / is the ˇ-hitting operator of X. Hence hGˇ g
GˇD g; giL2 D hHˇD Gˇ g; giL2 1 Eˇ .HˇD Gˇ g; Gˇ g/ ˇ 1 D Eˇ .HˇD Gˇ g; HˇD Gˇ g/ > 0: ˇ D
This establishes (12.50). Suppose that S D .S t / t >0 is a subordinator with Laplace exponent f given by Z f ./ D b C .1 e t /.dt/; > 0; .0;1/
12.3 Eigenvalue estimates for subordinate processes
163
with b > 0 or .0; 1/ D 1. Throughout this section we will assume that f .0C/ D 0. Let . t / t>0 be the convolution semigroup corresponding to S . Throughout this secf tion we will assume that X and S are independent. The process X f D .X t / t >0 f defined by X t WD X.S t / is called the subordinate process of X with respect to S ; this is again an m-symmetric Hunt process on E. The subordinate transition function f P t .x; dy/ of X f is given by Z 1 f P t .x; B/ D Ps .x; B/ t .ds/ for t > 0; x 2 E and B 2 B.E/: (12.51) 0
.Ef
; D.Ef
Let When b > 0,
// be the Dirichlet form corresponding to X f . Then D.E/ D.Ef /. D.E/ D D.Ef /
(12.52)
and for u 2 D.E/, Ef .u; u/ D bE.u; u/ C
Z .0;1/
hu
Ps u; uiL2 .ds/
Z D bE.u; u/ C
u.x/ E E
where J f .dx; dy/ WD and
1 2
2
u.y/ J .dx; dy/ C
.dx/ WD
u2 .x/ f .dx/; E
(12.53)
Z Ps .x; dy/ .ds/ m.dx/ .0;1/
Z
f
Z
f
Ps .x; E/ .ds/ m.dx/:
1 .0;1/
When b D 0, ² Z D.Ef / D u 2 L2 .E; m/ W and for any u 2 D.Ef /, Z f E .u; u/ D hu Z Jf
³ Ps u; uiL2 .ds/ < 1
(12.54)
Ps u; uiL2 .ds/
.0;1/
D
.0;1/
hu
u.x/ E E
2 u.y/ J f .dx; dy/ C
(12.55)
Z
u2 .x/ f .dx/; E
f
with and from above. For the above facts regarding .Ef ; D.Ef // we refer to f [229]. Let A be the L2 -infinitesimal generator of X f . It follows from Theorem 12.6, see also Example 11.6, that D.A/ D.Af /; Af u D bAu C
(12.56)
Z .Ps u .0;1/
u/ .ds/ for u 2 D.A/:
(12.57)
164
12 Subordination and Bochner’s functional calculus
By Proposition 12.5 we know that D.A/ is a core for the generator Af ; in particular, D.A/ is dense in .D.Ef /; Ef /. For every open subset D of E let X f;D denote the process obtained by killing X f f;D upon exiting from D. We will use .P t / t >0 to denote the transition semigroup of X f;D and Af;D to denote the generator of X f;D . The Dirichlet form of X f;D is .Ef;D ; D.Ef;D // where Ef;D D Ef and ® ¯ D.Ef;D / D u 2 D.Ef / W u D 0 Ef -q.e. on E n D : For u 2 D.Ef;D / we can rewrite Ef .u; u/ as Z Z 2 f f E .u; u/ D bE.u; u/C u.x/ u.y/ J .dx; dy/C u.x/2 f;D .x/ m.dx/; DD
where f;D .x/ D
Z .0;1/
D
Ps .x; E n D/ .ds/ C f .x/
(12.58) for x 2 D:
Let X D;f denote the process obtained by subordinating X D with the subordinaD;f tor S . The semigroup of X D;f will be denoted by .P t / t >0 and its generator by AD;f . The Dirichlet form of X D;f is .ED;f ; D.ED;f //, where ED;f is defined in the same way through X D as Ef is defined through X . For any u 2 D.ED;f /, Z 2 D;f u.x/ u.y/ J D;f .dx; dy/ E .u; u/ D bE.u; u/ C DD (12.59) Z C u2 .x/ D;f .x/ m.dx/; D
where J
D;f
1 .dx; dy/ D 2
and
D;f
Z .0;1/
PsD .x; dy/ .ds/ m.dx/
Z .x/ D
for x; y 2 D;
PsD 1.x/ .ds/ for x 2 D:
1 .0;1/
Theorem 12.39. Suppose that the Laplace exponent f of S is a complete Bernstein function. Then for any open subset D of E, we have D.ED;f / D.Ef;D / and Ef .u; u/ 6 ED;f .u; u/ for every u 2 D.ED;f /: Proof. Since f is a complete Bernstein function, it has the following representation Z 1 f ./ D b C .1 e t / m.t/ dt; 0
12.3 Eigenvalue estimates for subordinate processes
165
R where m.t/ D .0;1/ e ts s .ds/ and is the Stieltjes measure of f , see Remark 6.8. From Corollary 12.21 we know that Af has the following representation in terms of the L2 -generator A and the resolvent .Gˇ /ˇ >0 of X: Z Af u D bAu C .ˇGˇ u u/ .dˇ/ for u 2 D.A/: (12.60) .0;1/
For u 2 D.A/, it follows from (12.60) that f
Z
f
E .u; u/ D h A u; uiL2 D bE.u; u/ C Since D.A/ is E1 -dense in D.E/, Z f E .u; u/ D bE.u; u/ C
ˇhu
.0;1/
ˇhu .0;1/
ˇGˇ u; uiL2 .dˇ/:
ˇGˇ u; uiL2 .dˇ/ for u 2 D.E/:
Similarly, we have E
D;f
Z
D
.u; u/ D bE .u; u/ C
ˇhu .0;1/
ˇGˇD u; uiL2 .dˇ/ for u 2 D.ED /:
As D.ED / D.E/, we deduce from these formulae and (12.50) that for u 2 D.ED /, Z ED;f .u; u/ Ef .u; u/ D ˇ ˇhGˇ u GˇD u; uiL2 .dˇ/ > 0: .0;1/
f
Since D.AD / D.ED / is E1 -dense in D.ED;f /—see the comments after (12.57)—, we conclude that D.ED;f / D.Ef / and, therefore, that D.ED;f / D.Ef;D /. Moreover Ef .u; u/ 6 ED;f .u; u/ holds for every u 2 D.ED;f /. The semigroup .P t / t >0 is ultracontractive if each P t , t > 0, is a bounded operator from L2 .E; m/ to L1 .E; m/. Under this condition, for all t > 0 the transition operator P t has an integral kernel p.t; x; y/ with respect to the measure m, which satisfies 0 6 p.t; x; y/ 6 c t a.e. on E E (12.61) with t 7! c t being a non-increasing function on .0; 1/, see e.g. [73, (2.1.1) and Lemma 2.1.2]. Conversely, if for every t > 0 the transition operator P t has a bounded density function, i.e. if (12.61) holds for some c t > 0, then for a.e. x 2 E and every f 2 L2 .E; m/ Z 2 2 jP t f .x/j 6 p.t; x; y/ f 2 .y/ m.dy/ 6 c t kf kL 2 .E;m/ : E
So .P t / t >0 is ultracontractive. Therefore the semigroup .P t / t >0 is ultracontractive if, and only if, P t has a bounded integral kernel for every t > 0.
166
12 Subordination and Bochner’s functional calculus
In the remainder of this section we will assume that the semigroup .P t / t >0 of the process X is ultracontractive. Assume further that D is an open subset of E with m.D/ < 1. It is well known that under these assumptions the semigroup .P tD / t >0 of X D has a density with respect to m. We will denote this density by p D .t; x; y/. Under the assumption (12.61), it is easy to see that the subordinate process X f has a transition density p f .t; x; y/ given by Z 1 p f .t; x; y/ D p.s; x; y/ t .ds/: 0
Under the assumptions stated in the paragraph above, P tD is a Hilbert–Schmidt operator for t > 0. Thus for any t > 0, both P tD and AD have discrete spectra. We will use .e n t /n2N and . n /n2N to denote the eigenvalues of P tD and AD respectively, arranged in decreasing order and repeated according to multiplicity. f;D There are examples, see [67, Section 3], where for every t > 0, P t is not a f;D Hilbert–Schmidt operator. But, for every t > 0, P t is still a compact operator. f;D
Theorem 12.40. For every t > 0, P t therefore it has discrete spectrum.
is a compact operator in L2 .D; m/ and
Proof. For every s > 0 we define the operator Qs on L2 .D; m/ by Z Qs g.x/ WD p.s; x; y/ g.y/ m.dy/; g 2 L2 .D; m/: D
For g 2 L2 .D; m/ with kgkL2 .D;m/ 6 1 and any Borel subset A of D, we have Z Z 2 Qs g.x/ m.dx/ 6 Qs .g 2 /.x/ m.dx/ A A Z D g 2 .x/ Ps 1A .x/ m.dx/ E Z 6 kPs 1A k1 g 2 .x/ m.dx/ E
6 kPs 1A k1 ® ¯ 6 min 1; cs m.A/ :
(12.62)
Now we fix t > 0. For g 2 L2 .D; m/ with kgkL2 .D;m/ 6 1 and all Borel subsets A of D, we have 2 Z Z 1 Z Z 1 Qs g.x/ t .ds/ m.dx/ 6 jQs g.x/j2 t .ds/ m.dx/ A
A
0
Z D 0
0 1Z A
jQs g.x/j2 m.dx/ t .ds/:
12.3 Eigenvalue estimates for subordinate processes
For every > 0 we find some s0 > 0 such that t Œ0; s0 < 2
1
Z Z
Qs g.x/ t .ds/ A
dx 6
0
1 2
167
. Then by (12.62),
C cs0 m.A/: 2
This shows that for Borel sets A E with m.A/ < =2cs0 , we have 2
1
Z Z
Qs g.x/ t .ds/ A
m.dx/ 6
0
which entails that the family of functions ´Z µ 2 1 Qs g./ t .ds/ W kgkL2 .D;m/ 6 1 0
is uniformly integrable. f;D Let p f;D .t; x; y/ be the density function of P t . Clearly, p f;D .t; x; y/ 6 p f .t; x; y/;
.t; x; y/ 2 .0; 1/ D D:
Thus for all t > 0 and all Borel functions g on D, we have Z 1 Z f;D p f .t; x; y/ jgj.y/ m.dy/ 6 Qs jgj.x/ t .ds/: jP t g.x/j 6 D
0
Consequently, the family of functions ® f;D 2 ¯ .P t g/ W kgkL2 .D;m/ 6 1 is uniformly integrable on .D; B.D/; m/. By using this one can show that, for each f;D t > 0, P t is a compact operator in L2 .D; m/ and hence has discrete spectrum. f;D Indeed: assume that P t is not compact. Then there exist some > 0 and a f;D sequence .gn /n2N in A WD ¹P t=2 g W kgkL2 .D;m/ 6 1º such that f;D
kP t=2 gn
f;D
P t=2 gm kL2 .D;m/ > ;
n ¤ m:
Since we know that ¹g 2 W g 2 Aº is uniformly integrable, we have that Z lim sup g 2 .x/ 1¹jgj>Kº .x/ m.dx/ D 0; K!1 g2A D
f;D
and consequently, by the boundedness of P t=2 in L2 .D; m/, Z lim sup
K!1 g2A D
2 f;D P t=2 .g 1¹jgj>Kº /.x/ m.dx/ D 0:
168
12 Subordination and Bochner’s functional calculus
Therefore there exists some K > 0 such that f;D
kP t=2 gn;K
f;D P t=2 gk;K kL2 .D;m/ > ; 2
n ¤ k;
(12.63)
where gn;K D gn 1¹jgn j6Kº . Let C be the -algebra generated by .gn;K /n2N . Since L1 .D; C ; m/ is separable, the set .gn;K /n2N L1 .D; C ; m/ is weakly compact and metrizable with respect to the weak topology .L1 .D; C ; m/; L1 .D; C ; m//, cf. [57, IV.36, Lemma 1]. Therefore there exist g 2 L1 .D; C ; m/ and a subsequence .gnj ;K /j 2N such that for h 2 L1 .D; C ; m/ we have Z Z lim gnj ;K .x/ h.x/ m.dx/ D g.x/ h.x/ m.dx/: j !1 D
D
Without loss of generality, we will assume in the rest of this proof that m.D/ D 1, that is, m is a probability measure on D. For any h 2 L1 .D; m/ we will use m.h j C / to denote the conditional expectation of h with respect to C . Noting that for any h 2 L1 .D; m/ and k 2 L1 .D; C ; m/ we have Z Z k.x/ m.h j C /.x/ m.dx/; k.x/ h.x/ m.dx/ D D
D
we obtain that Z Z lim gnj ;K .x/ h.x/ m.dx/ D g.x/ h.x/ m.dx/ j !1 D
D
On the other hand, for every x 2 D, we have 2 f;D f;D P t=2 g.x/ P t=2 gnj ;K .x/ Z D p f;D .t=2; x; y/ g.y/ D
for all h 2 L1 .D; m/:
gnj ;K .y/ m.dy/
2
6 4K 2 :
Thus by the weak convergence of the sequence .gnj ;K /j 2N and the dominated converf;D
gence theorem we get that P t=2 gnj ;K .x/
j !1
f;D
! P t=2 g.x/ for every x 2 D. Since
f;D
f;D
the family ..P t=2 gnj;K /2 /j2N is uniformly integrable, we get that P t=2 gnj;K f;D P t =2 g
in
L2 .D; m/.
j !1
!
This contradicts (12.63) and the proof is complete. Q
In the remainder of this section, we will use . Q n /n2N and .e n t /n2N to denote f;D the eigenvalues of Af;D and P t , respectively, arranged in decreasing order and repeated according to multiplicity. Theorem 12.41. If the Laplace exponent f of the subordinator S is a complete Bernstein function, then Q n 6 f .n / for every n 2 N:
169
12.3 Eigenvalue estimates for subordinate processes
Proof. Since AD has discrete spectrum .n /n2N , the subordinate generator AD;f has discrete spectrum .f .n //n2N with the same eigenfunctions as AD . By the min-max principle for eigenvalues, see [242, Section XIII.1], and by Theorem 12.39 we get for every n 2 N Q n D
inf
L: subspace of L2 .D; m/ with dim L D n
6
inf
L2 .D; m/
L: subspace of with dim L D n
® ¯ sup Ef .u; u/ W u 2 L and hu; uiL2 .D;m/ D 1 ® ¯ sup ED;f .u; u/ W u 2 L and hu; uiL2 .D;m/ D 1
D f .n /: Here we are using the convention that for a Dirichlet form .E; D.E//, E.u; u/ D 1 when u 2 L2 .D; m/ n D.E/. This proves the theorem. Proposition 12.42. Suppose that S is a subordinator with Laplace exponent f . If there exists some C 2 .0; 1/ such that Px .X t 2 D/ 6 C;
for every t > 0 and every x 2 E n D;
(12.64)
then .1
C / D;f .x/ 6 f;D .x/ 6 D;f .x/
for x 2 D:
(12.65)
Proof. Recall that is the Lévy measure of S . For any x 2 D we have
f;D
Z .x/ D
Z
Z .0;1/
E nD
Ps .x; dy/ .ds/ C
Z D
1 .0;1/
1
Ps .x; E/ .ds/
.0;1/
Ps 1D .x/ .ds/
and D;f .x/ D
Z 1 .0;1/
PsD 1E .x/ .ds/:
Thus, the second inequality of (12.65) follows because p D .s; x; / 6 p.s; x; / for all .s; x/ 2 .0; 1/ D. In order to prove the first inequality, let D be the first exit time of D for the process X and let u.x; s/ D Px .Xs 2 D/. According to the assumption (12.64), u.x; t/ 6 C for every x 2 E n D and t > 0. By the strong Markov property of X we have for all x 2 D and t > 0 Px .D 6 t; X t 2 D/ D Ex 1¹D 6tº u.XD ; D / 6 C Px .D 6 t/:
170
12 Subordination and Bochner’s functional calculus
Therefore for all s > 0 and x 2 D, 1
Ps 1D .x/ D 1
PsD 1.x/
>1
PsD 1.x/
D .1
C/ 1
Px .D 6 t; X t 2 D/ C Px .D 6 t/ PsD 1.x/ :
This proves the first inequality of (12.65). A symmetric ˛-stable process in Rd , 0 < ˛ < 2, is a Lévy process X D .X t />0 taking values in Rd and with the characteristic exponent ./ D jj˛ , cf. Example 12.13. It is well known that the semigroup of this process is ultracontractive. Proposition 12.43. Let X be a symmetric ˛-stable process in Rd and let D be a bounded convex open and connected subset of Rd . Then 1 D;f .x/ 6 f;D .x/ 6 D;f .x/: 2 Proof. Because of the spherical symmetry of X we find for every bounded convex open connected subset D Rd 1 Px .X t 2 D/ < ; 2
for every t > 0 and x 2 E n D:
The assertion now follows from Proposition 12.42. It follows from Theorem 12.39 that D.ED;f / D.Ef;D /. From the expressions for the subordinate and killed subordinate jump measures J f and J D;f one easily concludes that J D;f .; / 6 J f .; /: (12.66) Theorem 12.44. Suppose that the Laplace exponent f of S is a complete Bernstein function. If X is a symmetric ˛-stable process in Rd and D is a bounded convex open and connected subset of Rd , then D.ED;f / D D.Ef;D / and 1 D;f .u; u/ 6 Ef .u; u/ 6 ED;f .u; u/; E 2
u 2 D.Ef;D /:
(12.67)
Proof. We know from Theorem 12.39 that D.ED;f / D.Ef;D /. On the other hand, by (12.52)–(12.55), (12.58)–(12.59) and Proposition 12.43, D.Ef;D / D.ED;f /. Thus D.ED;f / D D.Ef;D /. The inequality (12.67) follows immediately by combining Proposition 12.43 with (12.66) and Theorem 12.39. Theorem 12.44 together with the min-max principle for eigenvalues, see the proof of Theorem 12.41, immediately gives the following result for the eigenvalues f .n / of Af and Q n of Af;D .
12.3 Eigenvalue estimates for subordinate processes
171
Theorem 12.45. Suppose that the Laplace exponent f of S is a complete Bernstein function. If X is a symmetric ˛-stable process in Rd and D is a bounded convex open and connected subset of Rd , then 1 f .n / 6 Q n 6 f .n / for every n 2 N: 2 Comments 12.46. Sections 12.1 and 12.2: Subordination was introduced by Bochner in the short note [49] in connection with diffusion equations and semigroups. Using Hilbert space spectral calculus, Bochner points out that the generator of a subordinate semigroup is a function of the original generator. The name subordination seems to originate in Bochner’s monograph [50, Chapters 4.3, 4.4] where subordination of stochastic processes, their transition semigroups and generators is developed. A rigorous functional analytic and stochastic account is in the paper by Nelson [219] where, for the first time, the interpretation of subordination as stochastic time-change can be found; this was, independently, also pointed out by Woll [292] and Blumenthal [46]. Nelson is also the first to make the link between Bochner’s subordination and the rapidly developing theory of operator semigroups pioneered by Hille and Phillips. Phillips’ paper [235] contains the modern formulation of subordination of semigroups on abstract Banach spaces as well as the famous result on the form of the subordinate generator. An operational calculus for bounded generators of semigroups, based on the Dunford–Riesz functional calculus, is described in Hille and Phillips [133, Chapter XV]. For C0 -semigroups and unbounded generators this calculus is further developed in Balakrishnan [11] and [12]. The origins of subordination in potential theory can be traced back to the papers by Feller [99] and Bochner [49] where Riesz potentials of fractional order are discussed, and to Faraut [95] who studies fractional powers of Hunt kernels and a symbolic calculus induced by subordination and Bernstein functions, see also [96]. This line of research is continued by Hirsch who develops in a series of papers, [135, 136, 137, 138], a Bochner-type functional calculus for Hunt kernels and abstract potentials; his main motivation is the question which functions operate on Hunt kernels which was raised in the note by M. Itô [153] and generalized in [134]. In functional analysis, the study of fractional powers and functions of infinitesimal generators was continued by Nollau [225, 226, 227], Westphal [286], Pustyl’nik [241] and later by Berg, Boyadzihev and deLaubenfels [26] and Schilling [251, 252, 253]. Up-to-date accounts of subordination, mainly for Lévy processes and convolution semigroups, can be found in Sato [250, Chapter 6] and Bertoin [38]; fractional powers and related functional calculi are discussed in Martínez-Carracedo and Sanz-Alix [209]. The material on C0 -semigroups is mostly standard and can be found in many books on semigroup theory and functional analysis. Our sources are Davies [72], Ethier and Kurtz [92], Pazy [230] and Yosida [296]. An excellent exposition of dissipativity and fractional powers is in Tanabe [273, Chapter 2]. Remark 12.4 is modeled after Bochner [49], the proof of Proposition 12.5 is taken from [251], see also [157]. Phillips’ theorem appears for the first time in [235] where it is proved in the context of Banach algebras. Our proof of this theorem seems to be new. The results for the domains of subordinate generators are from [253]; Corollaries 12.8 and 12.9 are generalizations of the moment inequality in Pustyl’nik [241, Theorem 6] and Berg–Boyadzhiev–deLaubenfels [26, Prop. 5.14]; our method of proof is an improvement of [97, Prop. 1.4.9]. Observe that a combination of Corollary 7.12 or Proposition 7.13 and Theorem 12.22(v) with the estimate (12.19) leads to interesting new interpolation-type estimates. Take, for example f; g 2 CBF and ˛ 2 .0; 1/. Then f ˛ g 1 ˛ 2 CBF and kAf
˛g1 ˛
or, with f ˛ .ˇ /g 1 ˛ .1
f . A/ˇ ˛ g . A/1
˛
uk D kAf Ag
1 ˛
uk 6 4kAf uk˛ kAg uk1
˛
;
u 2 D.A/
(12.68)
ˇ/
and ˛; ˇ 2 Œ0; 1,
˛ 1 ˛ ˇ u 6 4 f . A/ˇ u g . A/1
ˇ
1 u
˛
;
u 2 D.A/:
(12.69)
Theorem 12.10 on the spectrum of the subordinate generator is from [235], the CBF-version is from Hirsch [136]. A predecessor of this is Balakrishnan [11, 12].
172
12 Subordination and Bochner’s functional calculus
The proof of Theorem 12.14 follows Schoenberg’s original argument [255] who considers completely monotone functions; the statement of the theorem is due to Bochner, but his proof in [50, pp. 99–100] is, unfortunately, incorrect. Lemma 12.15 is taken from [255]. The Bochner–Schoenberg theorem still holds on abelian groups if we cast it in the following form: determine all functions f which operate on the negative (resp. positive) definite functions, i.e. f ı is negative (resp. positive) definite for all negative (resp. positive) definite functions . Note that ./ D jj2 is indeed negative definite in the sense of Schoenberg, cf. Chapter 4. This is due to Herz [130] for positive definite functions and Harzallah [120, 121, 122] for negative definite functions; further generalizations are in Kahane [165]. The section on the functional calculus is a simplified and generalized version of [251, 253], see also [157, Chapter 4.3]. The presentation owes a lot to F. Hirsch who pointed out that the operator Ik appearf ing in Lemma 12.17 coincides with kRk . The idea to reduce the functional calculus to an operational calculus on the level of the trivial semigroup t 7! e ta , cf. Remark 12.25, is from Westphal [286] where this is worked out for fractional powers. That paper also contains the fractional power analogues of Theorem 12.30 and Corollary 12.31. This approach is heavily influenced by (abstract) approximation theory, see e.g. Butzer and Berens [59], in particular Chapter 2.3. The remarkable pointwise stability assertion for the functional calculus, Theorem 12.36, is an improvement of a similar result in [253]. The extension of the functional calculus sketched in Remark 12.37 is in line with the calculus developed in [241], and links our results with Hirsch’s theory on abstract potential operators: note that . A/ is essentially the inverse of the generator of a C0 -contraction semigroup, hence an abstract potential operator. Section 12.3: The recent study on the spectrum of the Dirichlet fractional Laplacian was initiated by .˛/ Bañuelos and Kulczycki in [14]. Suppose that D is a bounded open subset of Rd , let . Q n /n2N be the ˛=2 eigenvalues of . / jD , arranged in decreasing order and repeated according to multiplicity. Using a mixed Steklov problem for the Laplacian in Rd C1 it was shown in [14] that for bounded Lipschitz domains D Rd q .2/ .1/ for all n 2 N: Q n 6 Q n By considering a higher order Steklov problem, DeBlassie shows in [75] that for bounded Lipschitz domains D Rd and for any rational ˛ 2 .0; 2/ .˛/ .2/ Q n 6 .Q n /˛=2
for all n 2 N:
The upper bound above is shown for general subordinate Markov processes in [65], where a lower bound is also established. The exposition of this section is a combination of [65] and [67]. The last part of the proof of Theorem 12.40 is adapted from the proofs of [110, Lemma 3.1, Theorem 3.2]. For a general subordinator S whose Laplace exponent f is not necessarily a complete Bernstein function we have a weaker version of Theorem 12.39: that is, we always have D.ED;f / D.Ef;D / and Ef .u; u/ 6 4ED;f .u; u/ for all u 2 D.ED;f /: (12.70) This is due to the fact that PsD u 6 Ps u for all non-negative u 2 D.ED;f /, which allows to conclude from (12.51)–(12.55) that u 2 D.Ef / and Ef .u; u/ 6 ED;f .u; u/. For a general u 2 D.ED;f /, uC and u are both in D.ED;f /, and so we have that both uC and u are in D.Ef / and that Ef .uC ; uC / 6 ED;f .uC ; uC /; Thus u D uC
Ef .u ; u / 6 ED;f .u ; u /:
u 2 D.Ef /. The contraction property of Dirichlet forms yields ED;f .uC ; uC / 6 ED;f .u; u/;
ED;f .u ; u / 6 ED;f .u; u/:
Therefore we have D.ED;f / D.Ef;D / as well as (12.70). Using (12.70), we can see that the conclusions of Theorems 12.44 and 12.45 hold for a general subordinator S , with the exception that the upper bounds for Ef .u; u/ in (12.67) and for Q n have an additional multiplicative factor 4. Using the following formula for the first eigenvalue ® ¯ Q 1 D inf Ef .juj; juj/ W u 2 D.Ef;D / with kukL2 .D;m/ D 1
12.3 Eigenvalue estimates for subordinate processes
173
and the analogous formula for the first eigenvalue f .1 / for .ED;f ; D.ED;f //, we get that Q 1 6 f .1 / for a general subordinator. One can also prove that the eigenvalues of the generator of a killed subordinate Markov process depend continuously on the Laplace exponent of the subordinator. For this and related results, we refer to [66].
Chapter 13
Potential theory of subordinate killed Brownian motion
Recall that a Bernstein function f is a special Bernstein function if its conjugate function f ? ./ WD =f ./ is again a Bernstein function. Thus, the identity function factorizes into the product of two Bernstein functions. In this chapter we will use this factorization and show, as a consequence of Theorem 10.9, that the potential kernel of a strong Markov process Y is the composition of the potential kernels of two subordinate processes. As before, we call the subordinators associated with special Bernstein functions special subordinators. If the underlying process Y is a killed Brownian motion with an intrinsically ultracontractive semigroup, the factorization of the potential kernel implies a representation of excessive functions of Y as potentials of one of the subordinate processes. Let E be a locally compact separable metric space with the Borel -algebra B.E/. By Y D .Y t ; Px / t >0;x2E we denote a strong Markov process with state space E and semigroup .P t / t >0 . We will assume that the process Y is transient in the sense that R 1 there exists a positive measurable function g W E ! .0; 1/ such that x 7! 0 P t g.x/ dt is not identically infinite. The potential operator of the process Y is defined by Z 1 Gg.x/ D P t g.x/ dt; (13.1) 0
where x 2 E and g W E ! Œ0; 1/ is a measurable function. The function Gg is called the potential of g. Let f 2 SBF with the representation (10.1) and let f ? be its conjugate function given by (10.2). Further, let S D .S t / t >0 and T D .T t / t >0 be the special subordinators with Laplace exponents f; f ? 2 SBF and assume that S; T and Y are independent. The potential measures of S and T will be denoted f by U and V respectively. We define two subordinate processes Y f D .Y t / t >0 and ? ? f Y f D .Y t / t >0 by f
Y t D Y.S t / and Then Y f and Y f [56].
?
f?
Yt
D Y.T t /;
t > 0:
are again transient strong Markov processes on .E; B.E//, see
175
13 Potential theory of subordinate killed Brownian motion ?
?
Lemma 13.1. The potential operators G f and G f of Y f and Y f are given by Z f G g.x/ D P t g.x/ U.dt/; (13.2) Œ0;1/
?
G f g.x/ D
Z P t g.x/ V .dt/:
(13.3)
Œ0;1/
Proof. We will only show (13.2), the proof of (13.3) is similar. Let . t / t >0 be the convolution semigroup on Œ0; 1/ corresponding to f . The transition operators f .P t / t >0 of Y f are given by f
f
P t .x; A/ D Px .Y t 2 A/ D Px .Y.S t / 2 A/ Z D Px .Ys 2 A/ t .ds/ Œ0;1/
Z D
Ps .x; A/ t .ds/; Œ0;1/
where x 2 E and A 2 B.E/. For every non-negative Borel function g W E ! Œ0; 1/ it follows that Z 1 Z 1Z f P t g.x/ dt D Ps g.x/ t .ds/ dt G f g.x/ D 0
Œ0;1/
0
Z D
Ps g.x/ U.ds/: Œ0;1/
Throughout this chapter we will assume that b > 0 or .0; 1/ D 1. This implies that U.dt/ D u.t/ dt and V .dt/ D bı0 .dt/ C v.t/ dt where u; v W .0; 1/ ! .0; 1/ ? are non-increasing functions. Hence, the potential operators G f and G f can be written as Z 1 P t g.x/ u.t/ dt; (13.4) G f g.x/ D 0
G
f?
1
Z g.x/ D bg.x/ C
P t g.x/ v.t/ dt:
(13.5)
0
Moreover, by Theorem 10.9, we have Z t Z t bu.t/ C u.s/v.t s/ ds D bu.t/ C v.s/u.t 0
s/ ds D 1;
t > 0:
0
If the transition kernels .P t .x; dy// t >0 have densities p.t; x; y/ with respect to a reference measure m.dy/ on .E; B.E//, then the potential operator G will also have a density G.x; y/ given by Z 1 G.x; y/ D p.t; x; y/ dt: 0
176
13 Potential theory of subordinate killed Brownian motion
In this case one can define the potential of a measure on .E; B.E// by Z Z 1 G .x/ D G.x; y/ .dy/ D P t .x/ dt: E
0
Note that the potential of a function g can be regarded as the potential of the measure g.x/ m.dx/. Further, the potential operator G f will have a density G f .x; y/ given by the formula Z 1
G f .x; y/ D
p.t; x; y/u.t/ dt: 0
The factorization in the next proposition is similar in spirit to Corollary 12.24. Proposition 13.2.
(i) For any non-negative Borel function g on E we have ?
?
G f G f g.x/ D G f G f g.x/ D Gg.x/;
x 2 E:
(ii) If the transition kernels .P t .x; dy// t >0 admit densities, then for any Borel measure on .E; B.E// we have ?
G f G f .x/ D G .x/;
x 2 E:
?
Proof. (i) We are only going to show that G f G f g.x/ D Gg.x/ for all x 2 E. For ? the proof of G f G f g.x/ D Gg.x/ we refer to part (ii). Let g be any non-negative Borel function on E. Using (13.4), (13.5), Fubini’s theorem and Theorem 10.9 we get Z 1 ? ? G f G f g.x/ D P t G f g.x/ u.t/ dt 0 Z 1 Z 1 D P t bg.x/ C Ps g.x/ v.s/ ds u.t/ dt 0
0
D bG f g.x/ C
Z
D bG f g.x/ C
Z
1
1
Z Pt
0
Ps g.x/ v.s/ds u.t/ dt
0 1Z 1
P t Cs g.x/ v.s/u.t/ ds dt Z 1 Z 1 f D bG g.x/ C Pr g.x/ v.r t/dr u.t/ dt 0
0
D bG f g.x/ C
Z
0
t 1 Z r
u.t/v.r 0
1
Z D
0 r
Z
bu.r/ C 0
Pr g.x/ dr 0
D Gg.x/:
u.t/v.r
0 1
Z D
t/dt Pr g.x/ dr
t/dt Pr g.x/ dr
13 Potential theory of subordinate killed Brownian motion
177
(ii) Similarly as above, G
f?
f
1
Z
f
P t G f .x/ v.t/ dt Z 1 Z 1 f Ps .x/ u.s/ds v.t/ dt D bG .x/ C Pt
G .x/ D bG .x/ C
0
0
0
D bG f .x/ C
1Z 1
Z
P t Cs .x/ u.s/v.t/ ds dt Z 1 Z 1 f D bG .x/ C Pr .x/ u.r t/dr v.t/ dt 0
0
D bG f .x/ C 1
Z D
Z
t 1 Z r
u.r 0 r
Z
bC 0
0
t/v.t/dt Pr .x/ dr
0
u.r
t/v.t/dt Pr .x/ dr
0 1
Z D
Pr .x/ dr 0
D G .x/: In the rest of this chapter, we will always assume that the underlying Markov process Y is a Brownian motion killed upon exiting a bounded open connected subset D Rd . To be more precise, let X D .X t ; Px / t >0;x2Rd be a Brownian motion in Rd with transition density jx yj2 d=2 p.t; x; y/ D .4 t/ exp ; t > 0; x; y 2 Rd ; 4t and let D D inf¹t > 0 W X t … Dº be the first exit time of X from D. The process X D D .X tD ; Px / t >0;x2D defined by ´ X t ; t < D ; D Xt D @; t > D ; where @ is the cemetery point, is called the Brownian motion killed upon exiting D. The process X D is a Hunt process, and since D is bounded, it is transient. It will play the role of the process Y from the beginning of this chapter. The semigroup of X D will be denoted by .P tD / t >0 , and its transition density with respect to Lebesgue measure by p D .t; x; y/, t > 0, x; y 2 D. The potential operator of X D is given by Z 1 G D g.x/ D P tD g.x/ dt 0
and has a density
G D .x; y/
D
R1 0
p D .t; x; y/ dt,
x; y 2 D.
178
13 Potential theory of subordinate killed Brownian motion
Since the transition density p D .t; x; y/ is strictly positive, the eigenfunction '1 of the operator jD corresponding to the smallest eigenvalue 1 can be chosen to be positive, see for instance [73]. We assume that '1 is normalized so that R strictly 2 ' .x/ dx D 1. D 1 From now on we will assume that .P tD / t >0 is intrinsically ultracontractive, that is, for each t > 0 there exists a constant c t such that p D .t; x; y/ 6 c t '1 .x/'1 .y/;
x; y 2 D:
Intrinsic ultracontractivity of .P tD / t >0 is a very weak geometric condition on D. It is well known, cf. [74], that for a bounded Lipschitz domain D the semigroup .P tD / t >0 is intrinsically ultracontractive. For every intrinsically ultracontractive .P tD / t >0 there is some cQt > 0 such that p D .t; x; y/ > cQt '1 .x/'1 .y/;
x; y 2 D:
Let S D .S t / t >0 and T D .T t / t >0 be two special subordinators with conjugate Laplace exponents f; f ? 2 SBF given by (10.1) and (10.2), respectively. We retain the assumption that b > 0 or .0; 1/ D 1, and keep the notation for the potential measures U.dt/ D u.t/ dt and V .dt/ D bı0 .dt/ C v.t/ dt. Suppose that X, S and D;f T are independent and define the subordinate processes X D;f D .X t / t >0 and ? ? D;f X D;f D .X t / t>0 by D;f
Xt
D X D .S t /
D;f ?
and X t
D X D .T t /;
t > 0:
?
Then X D;f and X D;f are strong Markov processes on D. We call X D;f and ? X D;f subordinate killed Brownian motions. Their semigroups and potential op? D;f D;f ? erators will be denoted by .P t / t >0 , G D;f and .P t / t>0 , G D;f , respectively. Clearly, Z Z 1 D;f D G g.x/ D P t g.x/ U.dt/ D P tD g.x/ u.t/ dt; Œ0;1/
G
D;f ?
Z g.x/ D
Œ0;1/
0
P tD g.x/ V .dt/
1
Z D bg.x/ C 0
P tD g.x/ v.t/ dt;
where x 2 D and g is a non-negative Borel measurable function on D. By Proposi? ? tion 13.2 we have G D;f G D;f g D G D;f G D;f g D G D g for every Borel function ? g W D ! Œ0; 1/, and G D;f G D;f D G D for every measure on .D; B.D//. D;f Recall that a Borel function s W D ! Œ0; 1 is excessive for X D;f (or .P t / t >0 ), D;f D;f if P t s 6 s for all t > 0 and s D lim t !0 P t s. We will denote the family of ? D;f D;f all excessive function for X by S.X /. The notation S.X D / and S.X D;f / is now self-explanatory.
13 Potential theory of subordinate killed Brownian motion
179
A Borel function h W D ! Œ0; 1 is harmonic for X D;f if h is not identically infinite in D and if for every relatively compact open subset O O D, for all x 2 O; h.x/ D Ex h X D;f .O / ® ¯ D;f where O D inf t > 0 W X t … O is the first exit time of X D;f from O. We denote the family of all non-negative harmonic function for X D;f by HC .X D;f /. Similarly, HC .X D / denotes the family of all non-negative harmonic functions for X D . These are precisely those non-negative functions in D which satisfy h D 0 in D. Recall that if h 2 HC .X D / then both h and P tD h are continuous functions. It is easy to show that HC ./ S./, see the proof of Lemma 2.1 in [260]. D;f D;f D;f Let .G />0 be the resolvent of the semigroup .P t / t >0 . Then G is given by a kernel which is absolutely continuous with respect to Lebesgue measure. Moreover, one can easily show that for a bounded Borel function g vanishing outside a D;f compact subset of D, the functions x 7! G g.x/, > 0, and x 7! G D;f g.x/ are continuous. This implies, see e.g. [47, p. 266], that all functions in S.X D;f / are lower semicontinuous. ?
Proposition 13.3. If g 2 S.X D;f /, then G D;f g 2 S.X D /. Proof. First observe that if g 2 S.X D;f /, then g is the increasing limit of potentials G D;f gn for suitable non-negative Borel functions gn , cf. [71, p. 86]. Hence it follows from Proposition 13.2 that ?
?
G D;f g D lim G D;f G D;f gn D lim G D gn : n!1
n!1
?
Therefore, G D;f g is either in S.X D / or identically infinite since it is an increasing ? limit of excessive functions of X D . We prove now that G D;f g is not identically infinite. In fact, since g 2 S.X D;f /, there exists some x0 2 D such that for every t > 0, Z D;f
1 > g.x0 / > P t
1
g.x0 / D 0
PsD g.x0 / t .ds/;
where t is the distribution of S t . Thus there is some s > 0 such that PsD g.x0 / is finite. Hence Z Z 1 > PsD g.x0 / D p D .s; x0 ; y/g.y/ dy > cQs '1 .x0 / '1 .y/g.y/ dy; D
D
R
so we have D '1 .y/g.y/ dy < 1. Consequently Z Z ? D;f ? G g.x/ '1 .x/ dx D g.x/ G D;f '1 .x/ dx D D Z Z 1 D g.x/ b'1 .x/ C P tD '1 .x/ v.t/dt dx D
0
180
13 Potential theory of subordinate killed Brownian motion
Z D
D
Z D
D
1
Z
g.x/ b'1 .x/ C
e
1 t
'1 .x/ v.t/ dt dx
0 1
Z '1 .x/g.x/ dx b C
e
1 t
v.t/ dt
< 1:
0
?
Therefore G D;f g is not identically infinite in D. ?
Remark 13.4. Note that the proposition above is valid with X D;f and X D;f inter? changed: if g 2 S.X D;f /, then G D;f g 2 S.X D /. Proposition 13.2(ii) shows that if s D G D is the potential of a measure, then ? s D G D;f g where g D G D;f is in S.X D;f /. The function g can be written in the following way: Z 1 g.x/ D PrD .x/ u.r/ dr 0 Z 1 Z du.t/ dr D PrD .x/ u.1/ C .r;1/ 1
0
1
Z D 0
PrD .x/u.1/ dr
.0;1/
Z D u.1/s.x/ C
C 0 t
Z
Z D u.1/s.x/ C
Z
.0;1/
0
PrD .x/
PrD .x/ dr
P tD s.x/
Z du.t/
dr
.r;1/
du.t/
s.x/ du.t/:
(13.6)
In Proposition 13.8 below we will show that every s 2 S.X D / can be represented as ? a potential G D;f g, where g, given by (13.6), is in S.X D;f /. In order to accomplish this, we will first show that g is continuous when s 2 HC .X D /. Before we do this, we prove two preliminary results about non-negative harmonic functions of X D . For any x0 2 D, choose r > 0 such that B.x0 ; 2r/ D. Put B D B.x0 ; 2r/. Lemma 13.5. If h 2 HC .X D /, then there is a constant c > 0 such that h.x/
P tD h.x/ 6 ct;
x 2 B; t > 0:
Proof. For any x 2 B, h.X t ^B / is a Px -martingale. Therefore, 0 6 h.x/ P tD h.x/ D Ex h.X t ^B / Ex h.X t /1¹t<D º D Ex h.X t /1¹t<B º C Ex h.XB /1¹B 6tº Ex h.X t /1¹t<B º Ex h.X t /1¹B 6t<D º D Ex h.XB /1¹B 6t º Ex h.X t /1¹B 6t<D º 6 Ex h.XB /1¹B 6tº 6 M Px .B 6 t/;
13 Potential theory of subordinate killed Brownian motion
181
where M is a constant such that h.y/ 6 M for all y 2 B. It is a standard fact, cf. [16, Lemma I.(8.1)], that there exists a constant c > 0 such that for every x 2 B it holds that Px .B 6 t/ 6 ct , for all t > 0. Therefore, 0 6 h.x/ P tD h.x/ 6 Mct , for all x 2 B and all t > 0. D h.x/ and sn WD Lemma 13.6. If h 2 HC .X D /, define kn .x/ WD n h.x/ P1=n G D kn .x/. Then sn increases to h as n ! 1, and there exists c > 0 such that P tD sn .y/ 6 c t;
sn .y/
y 2 B; n 2 N:
Proof. The assertion that sn increases to h as n ! 1 follows from [15, Proposition II.(6.2)]. We only prove the second assertion. For any t > 0, n 2 N and y 2 B, we have Z t D sn .y/ P t sn .y/ D PrD kn .y/ dr 0
t
Z Dn 0
t
Z Dn 0
PrD .h
D P1=n h/.y/ dr
PrD h.y/ dr
t C n1
Z n
1 n
PrD h.y/ dr:
If t < n1 , then it follows from Lemma 13.5 that sn .y/
P tD sn .y/
t C n1
Z Dn
h.y/ 1 n
t C n1
Z 6n
h.y/ 1 n
t
Z dr
n
h.y/ 0
PrD h.y/ dr
PrD h.y/ dr
t C n1
Z 6 c1 n
PrD h.y/
r dr 6 c2 t:
1 n
If t > n1 , then again by Lemma 13.5 we have sn .y/
P tD sn .y/
1 n
Z Dn 0
t C n1
Z Dn
PrD h.y/ dr
t
t
6 h.y/
t
PrD h.y/ dr 1 n
Z 0
h.y/ PrD h.y/ dr
PrD h.y/ dr 1 D 6 c4 t: P t C 1 h.y/ 6 c3 t C n n h.y/
6n
n
h.y/ PrD h.y/ dr n
t C n1
Z
t C n1
Z
182
13 Potential theory of subordinate killed Brownian motion
Lemma 13.7. If h 2 HC .X D /, the function g defined by Z g.x/ D u.1/h.x/ C
P tD h.x/
.0;1/
h.x/ du.t/;
x 2 D;
(13.7)
is continuous. Proof. For any x0 2 D choose r > 0 such that B.x0 ; 2r/ D, and let B WD B.x0 ; r/. It follows from the continuity and harmonicity of h that there exists a constant c1 > 0 such that 0 6 h.x/ P tD h.x/ 6 c1 on B. Using Lemma 13.5 we know that there exists some c2 > 0 such that 0 6 h.x/
P tD h.x/ 6 c2 t;
x 2 B:
R Since .0;1/ .1 ^ t/. du.t// < 1, we can apply the dominated convergence theorem to get the continuity of g. Proposition 13.8. If s 2 S.X D /, then ?
s.x/ D G D;f g.x/;
x 2 D;
where g 2 S.X D;f / and is given by the formula 1
Z g.x/ D u.1/s.x/ C 0
P tD s.x/
s.x/ du.t/:
(13.8)
Proof. We know that the result is true when s is the potential of a measure. Let s 2 S.X D / be arbitrary. By the Riesz decomposition theorem, s D G D Ch, where is a measure on D and h is in HC .X D /, see e.g. [47, Chapter 6]. By linearity, it is enough to prove the result for s 2 HC .X D /. In the rest of the proof we assume therefore that s 2 HC .X D /. Define the function g by formula (13.8). We have to prove that g is excessive for X D;f and ? s D G D;f g. By Lemma 13.7, we know that g is continuous. D Define kn WD .s.x/ P1=n s.x// and sn WD G D kn .x/. It follows from Lemma 13.6 that sn increases to s. Thus P tD sn " P tD s and sn Z gn .x/ D u.1/sn .x/ C ?
sn .x/ .0;1/
P tD sn
n!1
P tD sn .x/
!s
P tD s. If
du.t/ ;
then we know that sn D G D;f gn and gn is excessive for X D;f . It follows from Lemma 13.6 that, for every x 2 D, 0 6 sn .x/ P tD sn .x/ 6 s.x/. Again by Lemma 13.6 there exists for every x 2 D some c > 0 such that 0 6 sn .x/
183
13 Potential theory of subordinate killed Brownian motion
R P tD sn .x/ 6 c t. Since .0;1/ .1 ^ t/. du.t// < 1, we can apply the dominated convergence theorem to get Z g.x/ D u.1/s.x/ C s.x/ P tD s.x/ du.t/ .0;1/
Z D lim u.1/sn .x/ C n!1
lim sn .x/
.0;1/ n!1
P tD sn .x/
du.t/
D lim gn .x/: n!1
By Fatou’s lemma and the fact that gn is G D;f -excessive, we get for any x 2 D and > 0 D;f D;f D;f lim gn .x/ 6 lim inf G gn .x/ G g.x/ D G n!1
n!1
6 lim inf gn .x/ D g.x/I n!1
this means that g is supermedian. Since it is well known that a supermedian function which is lower semicontinuous is excessive, cf. [71, p. 81], this proves that g ? is excessive for X D;f . By Proposition 13.3 we then have that G D;f g is excessive for X D . R1 For any non-negative measurable function h, let G1D h.x/ D 0 e t P tD h.x/ dt and define s 1 WD s G1D s. Using an argument similar to that of the proof of Proposition 13.3, we can show that G D s is not identically infinite. By the resolvent equation G D s 1 D G D s G D G1D s D G1D s, or equivalently, s.x/ D s 1 .x/ C G1D s.x/ D s 1 .x/ C G D s 1 .x/;
x 2 D: ?
Formula (13.6) for the potential G D s 1 , Fubini’s theorem and the fact that G D;f and G1D commute, show Z D D 1 D;f ? D 1 D D 1 D 1 .P t G s G s / du.t/ G1 s D G s D G u.1/G s C .0;1/
D G D;f
?
u.1/G1D s C
D G1D G D;f
?
Z .0;1/
Z u.1/s C
.0;1/
.P tD G1D s .P tD s
G1D s/ du.t/
s/ du.t/ :
By the uniqueness principle, see e.g. [71, p. 140], it follows that Z 1 ? D;f ? D sDG u.1/s C .P t s s/ du.t/ D G D;f g a.e. in D: 0
?
Since both s and G D;f g are excessive for X D , they are equal everywhere.
184
13 Potential theory of subordinate killed Brownian motion
Propositions 13.2 and 13.8 can be combined in the following theorem containing additional information on harmonic functions. Theorem 13.9. If s 2 S.X D /, then there is a function g 2 S.X D;f / such that ? s D G D;f g. The function g is given by the formula (13.6). Furthermore, if s 2 HC .X D /, then g 2 HC .X D;f /. Conversely, if g 2 S.X D;f /, then the func? tion s defined by s D G D;f g is in S.X D /. If, moreover, g 2 HC .X D;f /, then s 2 HC .X D /. Finally, every non-negative harmonic function for X D;f is continuous. Proof. It remains to show the statements about harmonic functions. First note that every g 2 S.X D;f / admits the Riesz decomposition g D G D;f C h where is a Borel measure on D and h 2 HC .X D;f /, see [47, Chapter 6]. We have already mentioned that functions in S.X D / admit such a decomposition. Since S.X D / and S.X D;f / are in one-to-one correspondence, and since potentials of measures of X D and X D;f are in one-to-one correspondence, the same must hold for HC .X D / and HC .X D;f /. The continuity of non-negative harmonic functions for X D;f follows from Lemma 13.7 and Proposition 13.8. Comments 13.10. The study of the potential theory of subordinate killed Brownian motions was initiated in [106] for stable subordinators and carried out satisfactorily in this case in [107]. The general case of special subordinators was dealt with in [261]. Our exposition follows that of [51, Section 5.5.2], but we provide a more elementary and direct proof of Proposition 13.8 here. Using Theorem 13.9, one can generalize some deep and important potential theoretic results for killed Brownian motions, like the Martin boundary identification and the boundary Harnack principle, to subordinate killed Brownian motions. For these results we refer to [107], [51, Section 5.5] and [261] where the underlying process X is a killed rotationally invariant ˛-stable process. Intrinsic ultracontractivity was introduced by Davies and Simon in [74]. It is a very weak regularity condition on D. For example, see [74], the killed semigroup .P tD / t >0 is intrinsically ultracontractive whenever D is a bounded Lipschitz domain. For weaker conditions on D guaranteeing that .P tD / t >0 is intrinsically ultracontractive, we refer to [13] and [17].
Chapter 14
Applications to generalized diffusions
Complete Bernstein functions and the corresponding Bondesson class of sub-probability measures play a significant role in various parts of probability theory. In this chapter we will explain their appearance in the theory of generalized one-dimensional diffusions (also called gap diffusions or quasi-diffusions). We have two main objectives: firstly, we want to characterize the Laplace exponents of the inverse local times at zero of generalized diffusions. It turns out that these are precisely the complete Bernstein functions. Secondly, we want to study the first passage distributions for generalized diffusions and to explain their connection with the Bondesson class and its subclasses. The crucial tool in these investigations will be Kre˘ın’s theory of strings which we will describe in some detail. In this chapter we will use Dirichlet forms and Hunt processes. The basic definitions and results are collected in Appendix A.2.
14.1
Inverse local time at zero
We start by introducing the family MC of the so-called strings. Definition 14.1. A string is a non-decreasing, right-continuous function m W R ! Œ0; 1 satisfying (a) m.x/ D m.0 / D 0 for all x < 0, (b) m.x0 / < 1 for some x0 > 0, (c) m.x/ > 0 for all x > 0. The family of all strings will be denoted by MC . We will use the same letter m to denote the measure on R induced by the nondecreasing function m 2 MC . Clearly, m. 1; 0/ D 0. Let r WD sup¹x W m.x/ < 1º be the length of the string, and let Em denote the support of the measure m restricted to Œ0; r/. Note that the point r of a possibly infinite jump is excluded from the support while 0 2 Em . Finally, let l WD sup Em 6 r. Next we introduce generalized diffusions. For this let B C D .B tC ; Px / t >0;06x
186
14 Applications to generalized diffusions
measure dx. In particular, there exists an associated Dirichlet form on L2 .Œ0; r/; dx/. Let L D .L.t; x// t >0; 06x
0: Œ0;r/
0
For m 2 MC the corresponding measure m on Œ0; r/ is a smooth measure in the sense of Definition A.15; note that no non-empty set is of capacity zero for B C . We define a positive continuous additive functional C D .C t / t >0 of the process B C by Z C t WD L.t; x/ m.dx/: (14.1) Œ0;r/
Clearly, the Revuz measure of C is equal to m. Let D . t / t >0 be the rightcontinuous inverse of C : t D inf¹s > 0 W Cs > t º. Define a process X D .X t / t >0 via the time-change of B C by the process , X t WD B C . t /. By [102, Theorem 6.2.1] X is an m-symmetric Hunt process on Em which is associated with a regular Dirichlet form on L2 .Em ; m/. Note that the lifetime of X is equal to C1 . Definition 14.2. The process X is called a generalized diffusion on Œ0; r/ (or, more precisely, on Em ). Clearly, X t D @ for t > . The class of such processes includes regular diffusions on Œ0; r/ and Œ0; l (in the sense of Itô–McKean), as well as birth-and-death processes. We will use the standard convention that any function g on the state space is automatically extended to @ by setting g.@/ D 0. The generalized diffusion X admits the local time process LX D .LX .t; x// t>0;x2Em which can be realized as a time-change of the local time of B C . More precisely, in the same way as in [246, Theorem V.49.1], it follows that LX .t; x/ D L. t ; x/ and Z s Z g.X t / dt D g.x/LX .s; x/ m.dx/; (14.2) 0
Œ0;r/
for every bounded measurable function g, and every s > 0. In particular, it follows from the joint continuity of L that x 7! LX .s; x/ is continuous. For simplicity, let us denote the local time at zero for X, LX .t; 0/, by `X .t/, and let .`X / 1 .t/ WD inf¹s > 0 W `X .s/ > tº be the inverse local time at zero. The inverse local time is a (possibly killed) subordinator, see, e.g. [36, p. 114]. Therefore we may assume that the Laplace exponent f of .`X / 1 has the representation Z f ./ D a C b C .1 e t / .dt/: .0;1/
14.1 Inverse local time at zero
187
An interesting problem is to characterize the family of Bernstein functions that can arise as Laplace exponents of inverse local times at zero of generalized diffusions. This question was raised in [152, p. 217] and solved, independently, in [176] and [182]. The answer is given in the following theorem. Theorem 14.3. Let X be a generalized diffusion corresponding to m 2 MC and let .`X / 1 be its inverse local time at zero. Then the Laplace exponent f of .`X / 1 belongs to CBF. Conversely, given any function f 2 CBF, there exists a generalized diffusion such that f is the Laplace exponent of its inverse local time at zero. The proof of this theorem relies heavily on Kre˘ın’s theory of strings. A full exposition of this theory would lead us far away from the topics of this book. Therefore, we will only outline the main ideas, and give more details for the parts of the proof where the methods are close to our subject. The first ingredient of the proof is probabilistic: for > 0 the -potential operator of X is defined by Z 1
G g.x/ WD Ex
t
e
g.X t / dt;
(14.3)
0
where x 2 Em and g is a non-negative Borel function on Œ0; r/. By Fubini’s theorem and (14.2), the -potential can be rewritten as Z s Z 1 s G g.x/ D Ex e g.X t / dt ds 0
0 1
Z D Ex
e
s
Z
g.y/L .s; y/ m.dy/ ds
Œ0;r/
Ex
e
s
LX .s; y/ ds g.y/ m.dy/
e
s
LX .ds; y/ g.y/ m.dy/
0
Z
Z D
1
Z
Z
Œ0;r/
Œ0;r/
0
D
X
Ex
Œ0;1/
Z D
G .x; y/g.y/ m.dy/:
(14.4)
Œ0;r/
Here G .x; y/ is the kernel of the -potential operator G defined by Z G .x; y/ WD Ex e s LX .ds; y/ ; x; y 2 Em :
(14.5)
Œ0;1/
Note that for each x 2 Em , the function y 7! G .x; y/ is continuous on Em . From now on, each function u defined on Em is linearly extended to Œ0; r/ n Em ; note that this does not uniquely determine the extension on .l; r/. This applies also to G .x; /. Proposition 14.4. For every > 0 it holds that G .0; 0/ D
1 : f ./
188
14 Applications to generalized diffusions
Proof. From (14.5) we have Z G .0; 0/ D E0
e Œ0;1/
1
Z D
t
E0 .e
Z
X
1
` .dt/ D E0
.`X /
1 .t/
.`X /
e 0 1
Z /dt D
e
0
tf ./
1 .t/
dt
dt D
0
1 : f ./
Note that, by Proposition 14.4 and Theorem 7.3, f 2 CBF if and only if 7! G .0; 0/ 2 S. In order to show that 7! G .0; 0/ 2 S, we are going to identify G .0; 0/ with the so-called characteristic function of the string and show that the latter is a Stieltjes function. To do so we need the analytic counterpart of generalized d diffusions, namely the second-order differential operator A D ddm dx which is for0 mally defined in the following way. The domain D .A/ of A consists of functions u W R ! C such that Z u.x/ D ˛ C ˇx C .x y/g.y/ m.dy/ Œ0;x
(14.6)
Z xZ D ˛ C ˇx C
g.w/ m.dw/ dy Œ0;y
0
where ˛; ˇ 2 C and g W R ! C. If x < 0 we interpret Œ0; x as the empty set ;, therefore u.x/ D ˛ Cˇx when x < 0. Then A is defined by Au WD g for u 2 D0 .A/. Every function u in D0 .A/ is absolutely continuous, linear outside of Em , and has right u0C and left derivatives u0 . More precisely, u.y/ D lim y y#x
u.x/ DˇC x
Z
u.y/ u .x/ D lim y y"x
u.x/ DˇC x
Z
u0C .x/ 0
g.y/ m.dy/;
(14.7)
g.y/ m.dy/:
(14.8)
Œ0;x
Œ0;x/
In particular, ˇ D u0 .0/. Moreover, for 0 6 x 6 l, u0C .x/
u0 .x/ D m¹xºAu.x/:
For z 2 C, let D .x; z/ and tions for x 2 Œ0; r/:
D
(14.9)
.x; z/ satisfy the following integral equa-
Z .x; z/ D 1 C z
.x
y/ .y; z/ m.dy/;
(14.10)
.x
y/ .y; z/ m.dy/:
(14.11)
Œ0;x
Z .x; z/ D x C z
Œ0;x
14.1 Inverse local time at zero
189
It can be shown that both equations above have unique solutions. We sketch the construction of . Let 0 .x/ 1 and define for n > 1 Z n .x/ WD .x y/ n 1 .y/ m.dy/: (14.12) Œ0;x
Expressing n as an n-fold integral, one can prove the following estimate, see [164, p. 32] or [89, p. 162] for details: n .x/ 6
.2x m.x//n .x m.x//n 6 : n n nŠ .2n/Š
Then .x; z/ WD
1 X
n .x/z n
(14.13)
(14.14)
nD0
converges and satisfies (14.10). Note that the equations (14.10) and (14.11) can be rewritten as A.; z/ D z.; z/, A .; z/ D z .; z/, with the boundary conditions .0; z/ D 1, 0 .0; z/ D 0, .0; z/ D 0 and 0 .0; z/ D 1. Here, and in the remaining part of this chapter, the derivatives are with respect to the first variable. In the remainder of this chapter we will use the following notational convention when working with the functions and : if the second argument z is a real number, we will write instead of z. The functions and have the following properties: (a) for each fixed x 2 Œ0; r/, z 7! .x; z/ and z 7! .x; z/ are real entire functions, i.e. they are analytic functions on C which are real if z 2 R; 0 (b) for all x 2 .0; r/ and > 0 we have .x; / > 0, C .x; / > 0, 0 and C .x; / > 0;
.x; / > 0
0 (c) for every z 2 C such that Im z ¤ 0 we have .x; z/ ¤ 0, C .x; z/ ¤ 0, 0 .x; z/ ¤ 0 and C .x; z/ ¤ 0.
Property (a) follows from (14.14) and the analogous equation for , and (b) follows from (14.12) and the analogous equations for ; (c) can be deduced from the following Lagrange identity: if u; v 2 D0 .A/, then for all x 2 Œ0; r/, Z v.y/Au.y/ u.y/Av.y/ m.dy/ Œ0;x (14.15) 0 0 0 0 D uC .x/v.x/ u.x/vC .x/ u .0/v.0/ u.0/v .0/ ; cf. [164, p. 24]. It follows from this that for any x 2 Œ0; r/ and z 2 C, .x; z/
0 C .x;z/
0 C .x; z/ .x; z/
D .x; z/
0
.x; z/
0 .x; z/ .x; z/ D 1:
(14.16)
190
14 Applications to generalized diffusions
Proposition 14.5. For x 2 Œ0; r/ and z 2 C n . 1; 0 define h.x; z/ WD
.x; z/ : .x; z/
Then h.x; / restricted to .0; 1/ belongs to S. Moreover, for 0 6 x < r, Z x 1 h.x; z/ D dy: z/2 .y; 0
(14.17)
Proof. If x D 0, then h.0; / 0, so there is nothing to prove. Thus we assume that x > 0. Since the denominator does not vanish, h.x; z/ is well defined for z 2 C n . 1; 0 and it is analytic on C n . 1; 0. We will show that h.x; / switches H" and H# , which proves the claim because of Corollary 7.4. For 0 6 y < r define x .y; z/ WD
.y; z/ C h.x; z/.y; z/;
(14.18)
and note that Ax .; z/ D zx .; z/ on Œ0; x. A straightforward calculation yields that 1 x .x; z/ D 0; .x /0C .x; z/ D ; .x; z/ (14.19) x .0; z/ D h.x; z/;
.x /0 .0; z/ D
1:
Let Im z ¤ 0. By the Lagrange identity (14.15) applied to x .; z/ and x .; z/, N and by (14.19), we get Z .z zN / x .y; z/x .y; z/ N m.dy/ Œ0;x
D .x /0C .x; z/x .x; zN / D Hence
.x /0C .x; z/ N x .x; z/ N .x /0 .0; z/.0; N z/ .x /0 .0; z/x .0; z/ h.x; z/ h.x; zN / D h.x; z/ h.x; z/ :
Z Im z Œ0;x
jx .y; z/j2 m.dy/ D
Im h.x; z/ :
Since Œ0;x jx .y; z/j2 m.dy/ > 0, we have that Im z Im h.x; z/ 6 0. The last statement of the proposition is a consequence of R
.x; z/ h.x; z/ D D .x; z/
x
Z 0
.y; z/ .y; z/
0
where the last equality follows from (14.16).
x
Z dy D 0
1 dy; .y; z/2
(14.20)
14.1 Inverse local time at zero
191
Let > 0 and 0 < x 6 y < r. Then y
Z .y; / > 1 C 1 .y/ D 1 C
m.w/ dw 0
y
y x : > m.w/ dw > m 2 2 x=2 Z
Therefore,
r
Z x
dy 4 6 2 2 .y; / m.x=2/2
r
Z x
(14.21)
dy < 1: y2
Since .; / is bounded away from zero on Œ0; x, it follows that Z r dy < 1; 2 0 .y; /
(14.22)
and it can be easily shown that Z lim
!1 0
r
dy D 0: .y; /2
Definition 14.6. The function h W .0; 1/ ! Œ0; 1/ defined by Z r dy .x; / h./ WD lim h.x; / D lim D 2 x!r x!r .x; / 0 .y; /
(14.23)
(14.24)
is called the characteristic function of the string m 2 MC . It follows from Proposition 14.5 and (14.22) that h is well defined. The next theorem is one of the fundamental results of Kre˘ın’s theory of strings. Theorem 14.7. (i) Let m 2 MC be a string. Then its characteristic function h is a Stieltjes function such that h.C1/ D 0, and hence it has the representation Z 1 h./ D .dt/; Œ0;1/ C t R where is a measure on Œ0; 1/ such that .0;1/ .1 C t/ 1 .dt/ < 1. (ii) Conversely, for any h 2 S such that h.C1/ D 0 there exists a unique string m 2 MC such that h is the characteristic function of m. Proof. (i) It was shown in Proposition 14.5 that h.x; / 2 S for every x 2 Œ0; r/. By Definition 14.6, h is a pointwise limit of Stieltjes functions which is, by Theorem 2.2(iii), again a Stieltjes function. Formula (14.23) implies that h.C1/ D 0, whence the form of the representation. (ii) The proof of the converse is beyond the scope of this book and we refer the interested reader to [89] and [164].
192
14 Applications to generalized diffusions
Remark 14.8. If we drop the requirement that m.x/ > 0 for every x > 0 in the definition of m 2 MC , then c WD inf Em may be strictly positive. The discussions leading to Theorem 14.7 remain almost literally the same, except that the limit in (14.23) turns out to be equal to c. Theorem 14.7 is then slightly extended to encompass all Stieltjes functions. Proposition 14.9. Let m 2 MC be a string and define for 0 6 x < r and > 0 the function .x; / WD .x; / C h./.x; /. Then Z r dy .x; / D .x; / ; (14.25) 2 x .y; / A.; / D .; / and 0 .0; / D
1.
Proof. By (14.24) and (14.20) r
Z .x; / D
.x; / C .x; / 0 x
Z D
.x; / 0 r
Z D .x; /
x
dy .y; /2
dy C .x; / .y; /2
r
Z 0
dy .y; /2
dy : .y; /2
That A.; / D .; / follows immediately from the same property of .; / and .; /, while 0 .0; / D 1 is a straightforward computation. For > 0 let ´ .x; /.y; /; R .x; y/ WD .x; /.y; /;
0 6 x 6 y < r; 0 6 y 6 x < r;
(14.26)
and note that by Proposition 14.9 R .0; 0/ D .0; /.0; / D h./: Thus, 7! R .0; 0/ 2 S, see also Remark 11.8. For g 2 L2 .. 1; r/; m/ define the -resolvent operator Z R g.x/ WD R .x; y/g.y/ m.dy/:
(14.27)
(14.28)
Œ0;r/
It is easy to prove that R is a bounded linear operator from L2 .. 1; r/; m/ to itself, see [89, p. 168]. In what follows we will need the L2 -domain of the operator A that appears in [89, p. 151].
193
14.1 Inverse local time at zero
Definition 14.10. Let L2 WD L2 .. 1; r/; m/. R (i) If l C m.l / D 1 and Œ0;r/ x 2 m.dx/ D 1, let ® ¯ D.A/ WD D0 .A/ \ u 2 L2 W Au 2 L2 ; u0 .0/ D 0 : R (ii) If l C m.l / D 1 and Œ0;r/ x 2 m.dx/ < 1, let ® ¯ D.A/ WD D0 .A/ \ u 2 L2 W Au 2 L2 ; u0 .0/ D u0C .l / D 0 : (iii) If l C m.l / < 1, let ® D.A/ WD D0 .A/ \ u 2 L2 W Au 2 L2 ; u0 .0/ D .r
¯ l/u0C .l/ C u.l/ D 0 : R Note, that in case (ii) of Definition 14.10, the assumption that Œ0;r/ x 2 m.dx/ < 1 implies m.l / < 1, hence r D l D 1. Therefore, u0C .l / D 0 means that limx!1 u0C .x/ D 0. In case (iii) it is more convenient to write the assumption in terms of the function u on Œ0; l. Note that by (14.9), u0C .l/ D u0 .l/ C m¹lºAu.l/. Thus, if r < 1, the condition .r l/u0C .l/ C u.l/ D 0 can be restated as m¹lºAu.l/ D u0 .l/ C
1 r
l
u.l/:
(14.29)
If r D 1, we may interpret the condition .r l/u0C .l/ C u.l/ D 0 as u0C .l/ D 0, which is equivalent to m¹lºAu.l/ D u0 .l/: (14.30) Lemma 14.11. Let g 2 L2 .. 1; r/; m/. Then u D R g solves the equation u Au D g. Moreover, R g 2 D.A/, and it is the unique solution of u Au D g belonging to D.A/. A proof of this lemma can be found in [89, Theorem on p. 167] and [164]. The next step is the identification of the probabilistic concept of the -potential with the analytic concept of the -resolvent. Let Cb .Em / denote the space of bounded continuous functions on Em Œ0; r/. For x 2 Em , and g 2 Cb .Em /, let Z 1 G g.x/ D Ex e t g.X t / dt: 0
Since G 1 6 1=, G g is well defined for all g 2 Cb .Em /. For x 2 Em set C TxB D inf¹t > 0 W B tC D xº and TxX D inf¹t > 0 W X t D xº. Then TxX D CT B C . x
Lemma 14.12. For all x 2 Em we have lim
Em 3y!x
TyX D TxX ;
Px
a.s.
(14.31)
194
14 Applications to generalized diffusions
Proof. Note that by the monotone convergence theorem, C tn ! C t as tn ! t. This proves that (14.31) is true as y ! x from the left. Suppose now that y ! x from the right. Then Z Z C X BC BC Ty D C.Ty / D L.Ty ; w/ m.dw/ D L.TyB ; w/ m.dw/ Œ0;l
Œ0;y
C
Px -a.s. where the last equality uses L.TyB ; w/ D 0 Px -a.s. for all w > y. Since m is finite on compact intervals, the claim follows by the dominated convergence theorem C C and the fact that TyB ! TxB Px -a.s. as y ! x. Lemma 14.13. G W Cb .Em / ! Cb .Em / and G W Bb .Em / ! Cb .Em /. Proof. Let g 2 Cb .Em / and x 2 Em . Assume that x is not isolated from the right within Em . We will prove the right-continuity of G g at x. Pick y > x; by the strong Markov property we find for all x; y 2 Em that ! Z X Ty
G g.x/ D Ex
e
t
TyX
C Ex .e
g.X t / dt
/G g.y/:
(14.32)
0
Letting y ! x we can use Lemma 14.12 to see that the first term on the right-hand X side of (14.32) converges to zero, while Ex .e Ty / converges to 1; thus G g.y/ ! G g.x/. In the same way one checks the left-continuity at points in Em which are not isolated from the left. The above argument uses only the fact that g 2 Bb .Em /, i.e. the second assertion of the lemma follows at once. Because of the resolvent equation, the range D WD G .Cb .Em // of G does not depend on > 0. Moreover, Z 1 t lim G g.x/ D Ex lim e g.X t / dt !1
!1
D Ex D Ex
Z lim
0 1
!1 0 Z 1 s
e
e
s
g.Xs= /
ds
g.X0 / ds
0
D g.x/; implying that G is one-to-one, hence invertible. Define AQ WD I
G 1 W D ! Cb .Em /
and note that, again by the resolvent equation, AQ does not depend on > 0.
14.1 Inverse local time at zero
195
For 0 < y < l and x; w 2 Œ0; y/ let C
GyB .x; w/ D .y
x/ ^ .y
w/
(14.33)
be the Green function of B C killed upon hitting y. Lemma 14.14. Let g W Œ0; y ! R be a bounded Borel function. Then for every x 2 Œ0; y/ Z TyX Z C Ex g.X t / dt D GyB .x; w/g.w/ m.dw/: Œ0;y
0
Proof. By a change of variables and Fubini’s theorem TyX
Z
C
C.TyB /
Z g.X t / dt D Ex
Ex 0
0
Z D Ex
C
g.B tC / C.dt/
C
g.B tC /
Œ0;TyB
Z D Ex
Œ0;TyB
Z D Z Œ0;y
Z D
Ex
Z L.dt; w/ m.dw/ Œ0;r/
!
Z Œ0;y
D
C g.B.t/ /dt
C
Œ0;TyB
g.B tC / L.dt; w/
m.dw/
C g.w/ Ex L.TyB ; w/ m.dw/ C
Œ0;y
g.w/ GyB .x; w/ m.dw/:
In the penultimate line we used that L.dt; w/ is supported on ¹B tC D wº, and in the last line we used the well-known formula relating the Green function and the local time for (reflected) Brownian motions. Let x 2 Em be positive and apply Dynkin’s formula for the stopping time TxX , see [152, pp. 98–99]. For u 2 D E0 u X.TxX /
TxX
Z u.0/ D E0 0
! Q Au.X t / dt :
196
14 Applications to generalized diffusions
By Lemma 14.14 and the obvious equality X.TxX / D x we get Z u.x/ D u.0/ C
C
Œ0;x
Q GxB .0; y/ Au.y/ m.dy/
Z D u.0/ C
.x
Q y/ Au.y/ m.dy/:
Œ0;x
Q and u0 .0/ D 0. This formula clearly shows that u 2 D0 .A/, Au D Au 2 Take g 2 Cb .Em / \ L .. 1; r/; m/ and > 0. Then G g 2 D D0 .A/, and Q g D G g AG g D AG i.e. G g
g;
AG g D g. Moreover, .G g/0 .0/ D 0.
Proposition 14.15. For every g 2 Cb .Em / \ L2 .. 1; r/; m/ we have G g D R g. Proof. Let g 2 Cb .Em /\L2 .. 1; r/; m/. In the paragraph preceding Lemma 14.14 it was shown that G g solves the equation u Au D g. If we show that G g 2 D.A/, the assertion follows by the uniqueness of the solution, cf. Lemma 14.11. Note that .G g/0 .0/ D 0. Also, G g 2 L2 .. 1; r/; m/ and AG g D G g g 2 L2 .. 1; r/; m/. that we are in case (i) of Definition 14.10, that is l C m.l / D 1 and R Suppose 2 m.dx/ D 1. Then there is nothing else to show, i.e. G g 2 D.A/. x Œ0;r/ Suppose now that we are in case (ii) of Definition 14.10, that is l C m.l / D 1 R and Œ0;r/ x 2 m.dx/ < 1. By the remark following Definition 14.10, it remains to show that limx!1 u0C .x/ D 0. Suppose that g > 0 and g vanishes on Œy; 1/ for some y 2 Em . By the strong Markov property we see for all x 2 Em that TyX
Z G g.x/ D Ex
! e
t
g.X t / dt
C Ex .e
TyX
/G g.y/;
(14.34)
0
and if x > y it follows that G g.x/ D Ex .e
TyX
/G g.y/:
(14.35)
X
Thus G g./ is proportional to E:.e Ty / on Œy; 1/ \ Em . Let y < x < v, y; x; v 2 Em . Again by the strong Markov property, Ev .e
TyX
/ D Ev .e
TxX
/Ex .e
TyX
/;
197
14.1 Inverse local time at zero
showing that x 7! Ex .e y < w < x. Then Ex .e
TyX
/ D Ex .e D Ex e
TyX
/ is decreasing. Furthermore, let w 2 Em be such that
TyX X Tw
C Ex e
1¹TwX
Ew .e
TvX
Ev .e
/1¹TwX
TyX
Since Px .TvX < TwX / D Px .TvB
C
1¹TvX
/1¹TvX
TyX
6 Px .TwX < TvX /Ew .e
TyX
/ C Px .TvX < TwX /Ev .e C
< TwB / D
v v
TyX
/:
x ; w
X
it follows that x 7! Ex .e Ty / is convex in Œy; 1/ \ Em (in the sense that, if we interpolate it linearly in Œy; 1/ n Em , it would be a convex function on Œy; 1/). Thus we know that x 7! G g.x/ is a non-negative decreasing and convex function on Œy; 1/ \ Em . This implies that limx!1 .G g/0C .x/ D 0. The case of g taking both signs follows by using g D g C g . Thus, G g D R g for all g 2 Cb .Em / \ L2 .. 1; r/; m/ having compact support. To finish the proof we use the fact that Cb .Em / \ L2 .. 1; r/; m/ \ Cc . 1; r/ is dense in L2 .. 1; r/; m/ and the continuity of G and R . Finally, assume that we are in case (iii) of Definition 14.10. We restrict ourselves to the case l < r < 1; the other two cases, l D r < 1 and l < r D 1, are similar. Assume that g > 0 and that g vanishes on Œy; l for some y 2 Em , y < l. For simplicity we write u D G g and we remark that u D Au on Œy; l. By the same argument as in case (ii) it follows that x 7! G g.x/ is decreasing on Œy; l. Moreover, since Pl .TyX < 1/ > 0, we get that u.l/ D El .e Since for x > y Z 0 u .x/ D
Œ0;x/
TyX
/ u.y/ > 0:
Z Au.w/ m.dw/ D
Z Œ0;y/
Au.w/ m.dw/ C
we see that u0 is non-decreasing on Œy; l. Further, Z u0 .l/ u0 .y/ D Au.w/ m.dw/ Œy;l/
Z D
u.w/ m.dw/ Œy;l/
6 u.y/ mŒy; l/ < 1;
u.w/ m.dw/; Œy;x/
198
14 Applications to generalized diffusions
implying that u0 .l/ < 1. By Dynkin’s formula we get Au.l/ D lim
x!l
Pl .TxX < 1/u.x/ El .TxX /
u.l/
:
(14.36)
This can be rewritten in the following form Au.l/ El .TxX / Pl .TxX < 1/.x l/ u.x/ D x
Pl .TxX < 1/ x l
u.l/ 1 C l
El .TxX / u.l/ C o.1/; x l
1
(14.37)
as x ! l. Note that Px .TyX < 1/ D Px .TxB
C
C
< TrB / D
Therefore, lim
Pl .TxX < 1/ x l
1
x!l
1
D lim
x!l
r x r l
1 x
l
r r
D
l : x 1 r
l
:
C
Let TrB denote the lifetime of B C (which is the same as the first hitting time to r of reflected (non-killed) Brownian motion), and recall that C
C
B El L.TxB ^ TrB ; w/ D G.x;r/ .l; w/ D
.l
x/.r w/ ; r x
B where G.x;r/ denotes the Green function of Brownian motion killed upon exiting the interval .x; r/. Therefore, Z C X El .Tx / D El .CT B C / D El L.TxB ; w/ m.dw/ x
Œ0;r/
Z D El
C
Œx;l
Z D
Œx;l
D
C C El L.TxB ^ TrB ; w/ m.dw/ .l
Z
C
L.TxB ^ TrB ; w/ m.dw/
x/.r w/ m.dw/; r x
Œx;l
and we conclude that lim
x!l
El .TxX / D x l
Z lim
x!l
Œx;l
r r
w m.dw/ D x
m¹lº:
14.1 Inverse local time at zero
199
If we let x ! l in (14.37) we get m¹lº Au.l/ D u0 .l/ C
1 r
l
u.l/;
which is (14.29). From this point onwards we can argue as in case (ii). This finishes the proof. Proof of Theorem 14.3. By (14.4) and (14.28), the statement of Proposition 14.15 can be written as Z Z G .x; y/g.y/ m.dy/ D R .x; y/g.y/ m.dy/ Œ0;r/
Œ0;r/
for all (non-negative) continuous functions g 2 L2 .. 1; r/; m/. For x 2 Em , both G .x; / and R .x; / are continuous on Œ0; r/. Hence it follows that G .x; y/ D R .x; y/ for all .x; y/ 2 Em Œ0; r/:
(14.38)
In particular, G .0; 0/ D R .0; 0/ D h./; which shows that 7! G .0; 0/ 2 S. This completes the proof of the direct part of Theorem 14.3. In order to prove the converse, let f 2 CBF and define h W .0; 1/ ! .0; 1/ by h./ D 1=f ./. Then h 2 S by Theorem 7.3, and Theorem 14.7 shows that there exists a unique string m 2 MC having h as its characteristic function. Let X D .X t / t >0 be a generalized diffusion corresponding to m. It is clear that the Laplace exponent of the inverse local time at zero of X is equal to f . Note that Theorem 14.3 and Theorem 14.7 give a one-to-one correspondence between f 2 CBF, m 2 MC and h 2 S with h.C1/ D 0. Unfortunately, the proofs do not give any insight into the explicit relationship between the Lévy triplet .a; b; / of f , the string m, and the Stieltjes measure of h. In the remainder of this section, we are going to establish some connections among them. Throughout the rest of this 1 section we adopt the convention that 10 D C1 and C1 D 0. We start with a probabilistic explanation of the connections between the Lévy triplet .a; b; / and the string m. Let us denote the local time at zero L.t; 0/ for B C by `.t/, and let ` 1 .t/ WD inf¹s > 0 W `.s/ > t º be the inverse local time of B C at zero. The inverse local time of X at zero, .`X / 1 , has the following representation: Z X 1 .` / .t/ D C` 1 .t/ D L ` 1 .t/; x m.dx/: (14.39) Œ0;1/
® ¯ C Note that inf t > 0 W .`X / 1 .t/ D 1 D `X ./ D `.TrB / where is the lifetime C C of X and TrB the lifetime of B C . Recall also the well-known fact that `.TrB / is
200
14 Applications to generalized diffusions
an exponential random variable with parameter r 1 , cf. [245, Proposition VI 4.6]. Hence, the lifetime of .`X / 1 is exponentially distributed with parameter r 1 , that is a D r 1 . Now we get from (14.39) and L.` 1 .t/; 0/ D t that Z .`X / 1 .t/ D m¹0º t C L ` 1 .t/; x m.dx/: .0;1/
The second term is a pure jump subordinator, hence the drift of .`X / 1 is m¹0º and b D m¹0º. Finally, we use the fact that .L.` 1 .t/; x// t >0 is for every x > 0 a subordinator with the Lévy density x 2 e =x , see [152, Problem 4, p. 73]. This implies that E0 ŒL.` 1 .1/; x/ D 1 for every x > 0. Hence, by (14.39) Z E0 .`X / 1 .1/ D E0 L.` 1 .1/; x/ m.dx/ D mŒ0; 1/: Œ0;1/
The connection between the Lévy triplet .a; b; / and the measure is straightforward. Indeed, Z Z 1 t .dt/ ; .1 e / .dt/ 1 D f ./h./ D a C b C Œ0;1/ C t .0;1/ and letting ! 0 proves that Z aD
Œ0;1/
.dt/ t
1
2 Œ0; 1/:
Similarly, 1D
f ./ h./ D
a 1 CbC
Z .1
e
t
Z / .dt/ Œ0;1/
.0;1/
and letting ! 1 gives b D Œ0; 1/ Z E0 .`X / 1 .1/ D b C
1
2 Œ0; 1/; letting ! 0 we get
.0;1/
t .dt/ D
1 2 .0; 1: ¹0º
This proves already our next result. Proposition 14.16. The following relations hold: 1 D E0 .`X / 1 .1/ ; ¹0º 1 D b; m¹0º D Œ0; 1/ Z .dt/ 1 rD D : t a Œ0;1/
mŒ0; 1/ D
.dt/ ; Ct
14.1 Inverse local time at zero
201
If the characteristic function h of the string is known, one can work out the Lévy triplet .a; b; / of f : let 1 h? ./ WD h./ be the Stieltjes function which is conjugate to h in the sense that f ? WD 1= h? is conjugate to f . Write Z c? 1 ? ? h ./ D Cd C ? .dt/ C t .0;1/ so that f ./ D h? ./ D c ? C d ? C D c? C d ? C
Z
1
Z
.1
.0;1/
? .dt/ Ct
e
t
/n? .t/ dt;
st
? .ds/
0
where ?
n .t/ D
Z se .0;1/
is the completely monotone density of . It can be shown, see [187] or [89], that h? is the characteristic function of the so-called dual string m? which is, by definition, the right-continuous inverse of the string m: m? .x/ WD inf¹y > 0 W m.y/ > xº. Finding explicitly the string m 2 MC such that a given f 2 CBF is the Laplace exponent of the inverse local time at zero of a generalized diffusion X corresponding to m is known as the Kre˘ın representation problem. Equivalently, the problem can be stated as follows: given g 2 CM, the density of the Lévy measure of f , d .d/ D g./ d, find the operator A D ddm dx which generates the generalized diffusion X. Surprisingly, there are very few examples of (classes of) completely monotone functions for which this problem has been solved. In the next table we record those classes with the corresponding operator A. The table was established by C. Donati-Martin and M. Yor in [81] and [82], except for the first row which is from [216].
c ; ˛C1 c ˛C1
e
;
0<˛<1
0 < ˛ < 1; > 0
d d d m dx 2 1 d ı 1 d WD C ; ı D 2.1 2 dx 2 2x dx p b 0˛ 2x d p K A ˛ C 2 ; p b ˛ 2x dx K AD
g./ A
˛
b ˛ .x/ WD x ˛ K˛ .x/; x > 0 K
˛/
202
14 Applications to generalized diffusions
AD
g./ c e c
sinh./
;
1 d2 C 2 dx 2
>0
˛C1
e .1
˛/
d d d m dx
! p b 0 2x p K 1 d 0 C 2 p b 0 2x 2x dx K
; A
˛
x
d dx
0 < ˛ < 1; > 0 c
sinh./
˛C1 ;
A
0<˛<1
˛ C x
b 0 .x 2 =2/ d K ˛=2 b K ˛=2 .x 2 =2/ dx
Explicit Kre˘ın representations
14.2
First passage times
We are now going to study the distributions of the first passage times of the generalized diffusion X. For y 2 Em define TyX WD inf¹t > 0 W X t D yº: Formula (14.5) states that Z G .x; y/ D Ex
s
e
LX .ds; y/ ;
Œ0;1/
x; y 2 Em ;
and since the local time LX .s; y/ is equal to zero for all times s < TyX , it follows from the strong Markov property that ! Z X G .x; y/ D Ex e s LX .ds; y/ D Ex .e Ty / G .y; y/: ŒTyX ;1/
Because of (14.26) and (14.38) we get Ex .e
TyX
/D
8 < .x;/ ; 0 6 x 6 y < r; .y;/
G .x; y/ D : .x;/ ; G .y; y/ .y;/
0 6 y 6 x < r:
Letting x ! 0C we see Px .TyX
< 1/ D
8 ˆ <1;
0 6 x 6 y < r; 0 6 y < x < r < 1;
: 1;
0 6 y < x < r D 1:
r x ; ˆr y
(14.40)
14.2 First passage times
We could also derive this formula from Px .TyB
C
be the distribution of TyX under Px . Then Ex Œe the first row of (14.40) gives that L .xy I / D
203
C
< TrB / D .y x/=.y r/. Let xy TyX
D L .xy I /. If 0 6 x < y,
.x; / : .y; /
(14.41)
In order to identify the class of distributions having this Laplace transform, we must study the zeroes of .x; / in greater detail. Assume that x > 0 and recall that for every z 2 C with Im z ¤ 0 we have 0 .x; z/ ¤ 0 and C .x; z/ ¤ 0. Hence, the only possible zeroes of .x; / are on the negative real axis. Since .x; / is analytic, the zeroes are discrete. Let .zj;x /j >1 be the family of all zeroes of .x; / arranged in decreasing order. Let < 0 and apply the Lagrange identity (14.15) to .x; / and .x; C h/, h 2 R sufficiently small, to get that Z 0 0 .x; C h/.x; / .x; C h/C .x; /: .y; C h/.y; / m.dy/ D C h Œ0;x
Dividing by h and letting h ! 0 yields Z @ 0 .x; / .y; /2 m.dy/ D .x; / C @ Œ0;x
0 C .x; /
@ .x; /: @
This means that all zeroes of .x; / are simple. In particular, for D zj;x the above equation becomes Z @ 0 .y; zj;x /2 m.dy/ D C .x; zj;x / .x; zj;x /; (14.42) @ Œ0;x 0 and we conclude that C .x; zj;x / and
@ .x; zj;x / @
have opposite signs.
Lemma 14.17. For each x 2 Œ0; r/, .x; z/ D
Y j
1
z zj;x
:
(14.43)
If m has at least n points of increase in .0; x/, then .x; / grows at least as fast as a polynomial of degree n. Proof. By (14.14) and (14.13) 1 p 1 X .2x m.x//n n X . 2xm.x/jzj/2n jzj D j.x; z/j 6 .2n/Š .2n/Š nD0 nD0 p p 6 exp 2x m.x/ jzj :
204
14 Applications to generalized diffusions
This shows that .x; / is an entire function of order at most 1=2, and the factorization (14.43) follows from Hadamard’s factorization theorem, cf. [208, Vol. 2, p. 289]. We show now the second statement of the lemma. First recall that both .; / and 0 C .; / are increasing for > 0. Let 0 < u < v < w. Since Z 0 C .v; / D .y; / m.dy/; Œ0;v
we conclude that for all > 0 Z Z 0 C .v; / > .y; / m.dy/ > .u;v
.u;v
This gives
w
Z .w; / D .v; / C w
Z > v
.u; / m.dy/ D .u; /m.u; v:
v
0 C .y; / dy
0 C .v; / dy
D .w
(14.44)
0 v/C .v; /
> .w
v/m.u; v .u; /:
We show now that .x; / grows at least as fast as a polynomial of degree n. Indeed, choose 2n C 1 points 0 < x0 < x1 < < x2n D x so that every interval .x2k 2 ; x2k 1 / contains a point of increase of m. Then m.x2k 2 ; x2k 1 > 0 for all k D 1; 2; : : : ; n. Using repeatedly the inequality (14.44) with x2k 2 < x2k 1 < x2k , we find n
.x; / >
n Y
.x2k
x2k
1/
kD1
> n
n Y
n Y
m.x2k
2 ; x2k 1 .x0 ; /
m.x2k
2 ; x2k 1 ;
kD1
.x2k
x2k
1/
kD1
n Y kD1
where we used that .; / > 1 for every > 0. This concludes the proof. Remark 14.18. One can adapt the argument used in in Lemma 14.17 to show that Y z .x; z/ D 1 ; (14.45) x wj;x j
where .wj;x /j >1 is the family of all zeroes of .x; / arranged in decreasing order. 0 0 The zeroes are also simple. Since C .x; z/.x; z/ .x; z/C .x; z/ D 1, it follows that .x; / and .x; / have no common zeroes.
14.2 First passage times
205
PAs a consequence of the convergence of the infinite product (14.43), the series j 1=jzj;x j < 1 converges. Moreover, if 0 < y < x, then .x; / may have more zeroes than .y; /. If there are infinitely many points of increase of m in .0; x/, then .x; / will have an infinite, but countable, number of zeroes. We discuss now the relative position of the zeroes of .x; / and .y; / for 0 < y < x. For simplicity assume that both .zj;x /j 2N and .zj;y /j 2N are infinite sequences. The argument when these sequences are of different length is similar, the difference being that some of the zeroes do not exist. Lemma 14.19. Assume that 0 < y < x. Then zj;y < zj;x < 0 for all j > 1. Proof. We begin with a few remarks that will be useful in the proof. First, since the zeroes of .x; / are simple, the function 7! .x; / changes sign every time it passes through a zero. Secondly, the function .x; / 7! .x; / is jointly continuous. Thirdly, .0; / 1, and also .; 0/ 1. Now fix x > 0. We claim that .y; / > 0 for all .y; / 2 A1;x WD Œ0; x Œz1;x ; 0 such that .y; / ¤ .x; z1;x /. This will prove that z1;y < z1;x for all 0 < y < x. Indeed, since z1;x is the largest zero of .x; /, it holds that .x; / > 0 for all 2 .z1;x ; 0. Suppose that there exists some .v; / 2 A1;x , .v; / ¤ .x; z1;x /, such that .v; / D 0. Because of the continuity of the minimum ® ¯ v1 D min v 2 Œ0; x W 9 2 Œz1;x ; 0 such that .v; / D 0 and .v; / 2 A1;x is attained. Since .0; / 1 and .x; / > 0 for all 2 .z1;x ; 0, we have 0 < v1 < x. Choose 1 2 Œz1;x ; 0/ such that .v1 ; 1 / D 0. Assume first that 1 > z1;x . Using the fact that the zeroes of .v1 ; / are discrete and that .v1 ; / changes sign every time it passes through a zero, we have, for sufficiently small > 0, either .v1 ; / < 0 for 2 .1 ; 1 /, or .v1 ; / < 0 for 2 .1 ; 1 C /. Assume that .v1 ; / < 0, 2 .1 ; 1 /. Since ¹ < 0º is open in A1;x , there would exist a point .v; / with v < v1 such that .v; / < 0. This, however, contradicts the minimality of v1 which entails that .v1 ; / > 0 for 2 .1 ; 1 /. The same argument yields .v1 ; / > 0 for 2 .1 ; 1 C / and sufficiently small > 0. This argument tells us that 1 6 z1;x . Hence, .v; / ¤ 0 for all .v; / 2 Œ0; x .z1;x ; 0. @ .x; z1;x / > 0 and We now rule out the possibility that 1 D z1;x . Indeed, since @ @ 0 0 .v ; z / > 0, it follows from (14.42) that .x; z / < 0 and C .v1 ; z1;x / < 0. 1 1;x 1;x C @ 0 This implies that there exists v 2 .v1 ; x/ such that .v; z1;x / D 0 and C .v; z1;x / > 0. On the other hand, we know already that z1;x is the largest zero of .v; /, i.e. @ 0 0 .v; z1;v / < 0, which z1;v D z1;x . By (14.42), C .v; z1;x / D C .v; z1;v / D @z is impossible. This concludes the proof that .v; / ¤ 0 for every .v; / 2 A1;x , .v; / ¤ .x; z1;x /. Thus, we have z1;y < z1;x for 0 < y < x.
206
14 Applications to generalized diffusions
We continue the proof by showing that z2;y < z2;x . Define ® ¯ A2;x WD .v; / W 0 6 v 6 x; z2;x 6 6 z1;v and note that < 0 immediately below the curve ¹.v; z1;v / W 0 6 v 6 xº. As above, by continuity there exists ® ¯ v2 D min v W 9 2 Œ0; x/ such that .v; / D 0 and .v; / 2 A2;x : Choose 2 such that .v2 ; 2 / D 0 and assume that 2 > z2;x . We argue in the same way as in the first part of the proof. Since the zeroes of .v2 ; / are discrete and since .v2 ; / changes sign every time it passes through a zero, we have, for sufficiently small > 0, either .v2 ; / > 0 for 2 .2 ; 2 /, or .v2 ; / > 0 for 2 .2 ; 2 C /. Suppose that .v2 ; / > 0, 2 .2 ; 2 /. Since ¹ > 0º is open in A2;x , there exists a point .v; / with v < v2 such that .v; / > 0. But this contradicts the minimality of v2 . Therefore, .v2 ; / < 0 for 2 .2 ; 2 /. The same argument yields that .v2 ; / < 0 for 2 .2 ; 2 C / and small enough > 0. This proves that it cannot happen that 2 > z2;x ; consequently, .v; / ¤ 0 for all .v; / 2 A2;x , with < z2;x . To rule out the possibility that 2 D z2;x we argue as in the first part of the proof. Thus, .v; / ¤ 0 and, in fact, .v; / < 0 for all .v; / 2 A2;x , .v; / ¤ .x; z2;x /. This proves that we have z2;y < z2;x for 0 < y < x. The inequalities zj;y < zj;x , j > 3, can be seen in the same way. Recall that xy is the distribution of the first passage time TyX at level y of the process X started at x. Theorem 14.20. If 0 6 x < y < r, then xy 2 BO and 0y 2 CE GGC. Proof. We begin with the case x D 0, that is 0y . By (14.41) and Lemma 14.17, we have 1 Y 1 L .0y I / D D 1C : .y; / jzj;y j j
Since the factors on the right-hand side are Laplace transforms of exponential distributions, Definition 9.14 shows that 0y 2 CE. Now suppose that x ¤ 0. Since x < Py, Lemma 14.19 shows that jzj;x j > jzj;y j. A consequence of Lemma 14.17 is that j 1=jzj;y j < 1. Hence, Y .x; / L .xy I / D D 1C 1C .y; / jzj;x j jzj;y j
1
j
is well defined and strictly positive. Corollary 9.16 tells us that xy 2 BO.
14.2 First passage times
207
In the remaining part of this chapter we will give a more precise description of the first passage distributions of generalized diffusions. All generalized diffusions which we have studied so far live on Em Œ0; r/ and are, in fact, generalized reflected diffusions. We will now consider generalized diffusions on open intervals of the type . r1 ; r2 /, 0 < r1 ; r2 6 1. The definition of these processes follows closely the one of generalized reflected diffusions. Let m W R ! Œ 1; 1 be a non-decreasing, right-continuous function with m.0 / D 0. The family of all such functions will be denoted by M. We use the same letter m to denote the measure on R corresponding to m 2 M. We associate with m 2 M two functions m1 ; m2 W Œ0; 1/ ! Œ0; 1 defined by ´
m.. x/ /; m1 .x/ D 0;
´
x > 0; x < 0;
and
m2 .x/ D
m.x/; 0;
x > 0; x < 0:
Both m1 and m2 are non-decreasing and right-continuous, m1 .0/ D m.0 / D 0 and m2 .0/ > 0. For i D 1; 2, ri D sup¹x W mi .x/ < 1º 6 1, let Emi be the support of mi restricted to Œ0; ri /, and note that 0 2 Emi need not hold. Set li WD sup Emi 6 1. In view of Remark 14.8, we may regard mi as a string of length ri . Let B D .B t ; Px / t >0; r1 <x0; r1 <x
L.t; x/ m.dx/: . r1 ;r2 /
By D . t / t >0 we denote the right-continuous inverse of C . Define a process X D .X t / t >0 via the time-change of B by the process , X t WD B.t/ . In the same way as in the beginning of this chapter we conclude that X is a strong Markov process with state space Em D supp.mj. r1 ;r2 / / which is called a generalized diffusion on . r1 ; r2 / or, more precisely, on Em . We write to denote the lifetime of X. For z 2 C let i .x; z/ and i .x; z/, i D 1; 2, be the solutions of the equations Z i .x; z/ D 1 C z .x y/i .y; z/ mi .dy/; 0 6 x < ri ; Œ0;x
Z i .x; z/
Define .; z/ and ´
DxCz
.x
y/
i .y; z/ mi .dy/;
0 6 x < ri :
Œ0;x
.; z/ on . r1 ; r2 / by
1 . x; z/; .x; z/ D 2 .x; z/;
x < 0; x > 0;
´ and
.x; z/ D
1.
x; z/; 2 .x; z/;
x < 0; x > 0:
208
14 Applications to generalized diffusions
Then it is straightforward to check that ´ R 1 z Œ0;x .x y/.y; z/ m.dy/; r1 < x < 0; .x; z/ D R 1 C z Œ0;x .x y/.y; z/ m.dy/; 0 6 x < r2 ; ´ R x z Œ0;x .x y/ .y; z/ m.dy/; r1 < x < 0; .x; z/ D R x C z Œ0;x .x y/ .y; z/ m.dy/; 0 6 x < r2 :
(14.46)
(14.47)
For > 0 let h1 ./ D lim
x!r1
1 .x; /
1 .x; /
D lim
x!r1
. x; / D . x; /
lim
x! r1
.x; / .x; /
be the characteristic function of the string m1 , and define h2 ./ in an analogous way for the string m2 . Set 1 h./ WD h1 ./ 1 C h2 ./ 1 : For a bounded Borel function g W . r1 ; r2 / ! R and x 2 Em , let Z 1 G g.x/ D Ex g.X t / dt; > 0: 0
As in the case of generalized reflected diffusions, one can show that the operator G admits a kernel G .x; y/ given by the formula G .x; y/ D h./ .x; / C h1 ./ 1 .x; / .y; / h2 ./ 1 .y; / ; for x; y 2 Em with x 6 y, see [182, p. 247]. For y 2 Em , let TyX D inf¹t > 0 W X t D yº. In the same way as before one derives that for all x; y 2 Em G .x; y/ D Ex Œe
TyX
G .y; y/:
(14.48)
If r2 < 1 and r2 2 E m , define EQ m D Em [ ¹r2 º; otherwise, set EQ m D Em . In case r2 2 EQ m , set TrX2 WD limy!r2 TX . Later in this chapter we will need the following lemma. Rr Lemma 14.21. (i) If r2 2 EQ m , then 0 2 m.x/ dx < 1 if, and only if, .r2 ; / < 1. (ii) If the representingP measure of h2 is supported by a sequence of positive numbers .ai /i >1 such that R i >1 1=ai < 1, and if r2 < 1, then either m.r2 / < 1, or r m.r2 / D 1 and 0 2 m.x/ dx < 1. Proof. (i) One direction follows from (14.21), while the other can be found in [89, p. 163]. (ii) For this part we refer the reader to the paper [163].
209
14.2 First passage times
Proposition 14.22.
(i) For > 0 and y 2 . r1 ; r2 / let
h2 .y; / D
.y; / .y; /
and h.y; / WD
Then E0 Œe
TyX
D
h.y; / .y; /
and P0 .TyX
< 1/ D
1 1 h1 ./
C
1 h2 .y;/
for every > 0
´ 1; r1 r1 Cy ;
.r2 ; / WD
TyX
D
R r2 0
m.x/ dx <
.r2 ; / < 1.
Proof. (i) Recall that .0; / D 1 and E0 Œe
(14.49)
r1 D 1; r1 < 1:
(ii) Suppose that r2 2 EQ m . Then P0 .TrX2 < 1/ > 0 if, and only if, 1. In this case X h./ E0 Œe Tr2 D ; for every > 0 .r2 ; / where
:
.0; / D 0. It follows from (14.48) that
1 G .0; y/ D G .y; y/ .y; / C h./ 1 .y; / 1 D .y; / h2 .y; / 1 C h1 ./ 1 D
(14.50)
h.y; / : .y; /
X For the second statement note that P0 TyX < 1 D lim!0 E0 Œe Ty . It follows from the last formula of Proposition 14.16 that lim!0 h1 ./ D h1 .0/ D r1 , while lim!0 h2 .y; / D .y; 0/=.y; 0/ D y. Hence ´ 1; r1 D 1; h.y; / lim D r1 !0 .y; / r1 Cy ; r1 < 1: R r2 (ii) Under the assumption r2 2 EQ m Lemma 14.21 R r2 proves that 0 m.x/ dx < 1 if, and only if, .r2 ; / < 1. Suppose that 0 m.x/ dx D 1 and let y ! r2 X
in (14.50). We get E0 Œe Tr2 D 0, hence P0 .TrX2 < 1/ D 0. Assume now that R r2 0 m.x/ dx < 1. Since h./ D limx!r2 .x; /= .x; / and since .r2 ; / < 1 by Lemma 14.21(i), we have that .r2 ; / < 1. Let y ! r2 in (14.49). It follows that X h./ E0 Œe Tr2 D ; .r2 ; / and since the right-hand side is strictly positive, P.TrX2 < 1/ > 0.
210
14 Applications to generalized diffusions
Remark 14.23. Since both h1 and h2 .y; / are in S, it follows that h.y; / 2 S as well. For x 2 Em and y 2 EQ m such that x < y let xy be the Px -distribution of TyX . Define ® ¯ H WD xy W x 2 Em ; y 2 EQ m ; x < y; m 2 M to be the family of all such first passage distributions. Translating the function m, if necessary, it is enough to consider x D 0. Theorem 14.24. A sub-probability measure belongs to H if, and only if, there exist 1 2 CE and 2 2 ME with 2 ¹0º D 0 such that D 1 ? 2 , the representing sequence .bj /j >1 of 1 is either empty or strictly increasing, and the representing measure of 7! . L .2 I // 1 has a point mass at every bj . Proof. Suppose that D 0y 2 H. By (14.17) we have that Y y 1 D .y; z/ j
z wj;y
1
Y z D 1C bj
1
;
(14.51)
j
where bj WD jwj;y j and .wj;y /j >1 are the zeroes of .y; /. Since the zeroes .wj;y /j >1 are simple and decreasing, the sequence .bj /j >1 is increasing. Note that the righthand side of (14.51) is the Laplace transform of a probability measure from CE, cf. Corollary 9.16, so we may define 1 2 CE by L .1 I / WD y= .y; /, > 0. Moreover, 7! h.y; /=y 2 S and h.y; 0/=y 6 1 by Proposition 14.22. It follows by Definition 9.4 that there exists 2 2 ME such that L .2 I / D h.y; /=y. From Proposition 14.22 we have that L .I / D
h.y; / D .y; /
y h.y; / D L .1 I /L .2 I /; .y; / y
that is, D 1 ? 2 . Since h2 .y; / 2 S, the function 7! .h2 .y; // 1 D .y; /=. .y; // also belongs to S. By Remark 14.18, .y; / and .y; / have no common zeroes, i.e. the set of poles of 7! .y; /=. .y; // is precisely ¹0º [ ¹wj;y W j > 1º. Hence, the set ¹0º [ ¹bj W j > 1º is the support of the representing measure of 7! .h2 .y; // 1 . Since 1 1 1 C D ; h.y; / h1 ./ h2 .y; / the representing measure of 7! .h.y; // set ¹0º [ ¹bj W j > 1º. But
1
has a point mass at each point in the
y 1 D ; L .2 I / h.y; /
14.2 First passage times
211
showing that the representing measure of 7! .L .2 I // 1 has a point mass at every bn . It remains to check that 2 ¹0º D 0. Note that 2 ¹0º D lim!1 L .2 I / D lim!1 h.y; /=y. By the definition of h.y; / it suffices to show that at least one of the limits lim!1 h1 ./ and lim!1 h2 .y; / is equal to zero. But this follows from (14.23) and the fact that 0 is a point of increase for at least one of the measures m1 and m2 , cf. Remark 14.8. Sufficiency: By assumption we have that ´ 1; 1 L .1 I / D Q ; j 1C b j
if ¹bj W j > 1º D ;; otherwise:
Since 2 2 ME it follows that L .2 I / 2 S as well asR ! .L .2 ; // 1 2 S. Therefore, there exist c > 0 and a measure Q satisfying Œ0;1/ .1 C t/ 1 .dt/ Q <1 such that Z 1 1 DcC .dt/ Q L .2 I / Œ0;1/ C t and that Q has a point mass at each point in ¹0º [ ¹bj W j > 1º. Since
L .2 I / D c C
Z Œ0;1/
.dt/ Q Ct
1
;
we conclude that ¹0º Q D L .2 I 0/ 1 > 1. As 2 ¹0º D 0 we can let ! 1 to find c > 0 or Œ0; Q 1/ D 1. Write Q as Q 1 C Q 2 where supp.Q 2 / D ¹0º [ ¹bj W j > 1º and Q 2 ¹0º D ¹0º Q > 1. Thus Q 1 ¹0º D 0. By (7.3) we see that there exist measures 1 and 2 on Œ0; 1/, and real numbers c1 > 0, c2 > 0, such that Z 1 Z 1 1 .dt/ D Q 1 .dt/ c1 C ; (14.52) Œ0;1/ C t .0;1/ C t 1 Z Z 1 : (14.53) c2 C 2 .dt/ D c C Q 2 .dt/ Œ0;1/ C t Œ0;1/ C t Denote the functions defined in (14.52) and (14.53) by g1 and g2 respectively. Then 1 L .2 I / D g1 ./ 1 C g2 ./ 1 : (14.54) We record the following facts that follow from (14.52) and (14.53) by letting ! 1: (a) c1 D 1=Q 1 .0; 1/; (b) if c D 0, then c2 D 1=Q 2 Œ0; 1/, while if c > 0, then c2 D 0; (c) c1 c2 D 0; indeed, if c D 0, then Œ0; Q 1/ D 1, so that either Q 1 Œ0; 1/ D 1 or Q 2 Œ0; 1/ D 1.
212
14 Applications to generalized diffusions 1
Further, g1 .0/ D Q 1 ¹0º D 1 and g2 .0/ D Q 2 ¹0º
2 .0; 1. Note that we can write
X 1
j D c C 0 C g2 ./ C bj j >1
where j is the mass of Q 2 at bj , j > 0. This shows that 1=g2 has real poles at bj , j > 1, hence also real zeroes aj , j > 1, which intertwine with the poles: 0 < a1 < b1 < a2 < b2 < . Therefore, Q j 1 C bj (14.55) g2 ./ D Q : j 1 C aj PThis shows that the representing measure of g2 is supported in .ai /i >1 and i >1 1=ai < 1. Let m1 and m2 be strings having g1 and g2 as their characteristic functions. Since g2 .0/ 2 .0; 1, it follows that the length r2 of the string m2 satisfies r2 D g2 .0/ 2 .0; 1. Moreover, R r by Lemma 14.21(ii) we conclude that either m.r2 / < 1, or m.r2 / D 1 and 0 2 m.x/ dx < 1. In the second case it holds that r2 2 EQ m . In the first case one can extend m2 without changing its characteristic function g2 such that the length of the extended m2 is strictly larger than r2 —e.g. extend m2 to be the constant m.r2 / on an interval to the right of r2 . We use the same letter for the extended string. Next 1 Œ0; 1/ D lim g1 ./ D !1
1 lim!1
1 .0;1/ Ct
R
Q 1 .dt/
D 1;
hence by the second line in Proposition 14.16 we get that m1 ¹0º D 0. Define m by ´ m1 .. x/ /; x < 0; m.x/ D m2 .x/; x > 0: Then m 2 M. Let .; / and .; / be the solutions of equations (14.46) and (14.47) with this m. Then clearly g1 and g2 can be expressed in terms of and as .x; / ; .x; / .x; / .r2 ; / g2 ./ D lim D : x!r2 .x; / .r2 ; / g1 ./ D
lim
x! r1
Comparing the last formula with (14.55) we see that the family of all the zeroes of .r2 ; / is equal to ¹ bj W j > 1º. Hence, Y .r2 ; / D 1C ; bj j
14.2 First passage times
213
implying that L .1 I / D
1 : .r2 ; /
Together with (14.54) this gives that L .I / D L .1 I / L .2 I / D
g./ .r2 ; /
where g./ WD .g1 ./ 1 C g2 ./ 1 / 1 . Since c1 D 0 or c2 D 0, we see that 0 is in the support of m. Hence, it follows from Proposition 14.22 that is the hitting time distribution of r2 starting at 0 for the generalized diffusion corresponding to m. Comments 14.25. Kre˘ın’s theory of strings was developed by M. G. Kre˘ın in the period from 1951 to 1954 in a series of papers [183, 184, 185, 186, 187]. An excellent exposition of these results is given in [164] which also contains historical and bibliographical remarks on the subject. An equally good source for the theory of strings are Chapters 5 and 6 of [89]. Our presentation is a combination of those two references. A complete proof of Theorem 14.7 can be found in either of these references. Definition 14.10 is from [89] as well as Lemma 14.11 which says that R W L2 .. 1; r/; m/ ! D.A/ is one-toone and onto. The image of L2 .. 1; r/; m/ under R is dense in L2 .. 1; r/; m/ and both R and A are self-adjoint. Applications of Kre˘ın’s string theory to Markov processes are studied in the 1970’s. It seems that Langer, Partzsch and Schütze are the first to use this connection in [198] where it is shown that the operator A (acting on an appropriate domain) is the infinitesimal generator of a C0 -semigroup. Path properties of the corresponding Feller process are studied by Groh in [113]. S. Watanabe, [285] gives the first construction of the process as a time-change of (reflected) Brownian motion and introduces the name quasi-diffusion. This name is adopted by Küchler in [190, 191] and [192] who looks at the properties of transition densities of the process. The name generalized diffusion is probably introduced by N. Ikeda, S. Kotani and S. Watanabe in [145], and is used again by Tomisaki, [276]. Related works are [166, 181] and [167]. The term gap diffusion is used by Knight in [176]. The question of characterizing Lévy measures of inverse local times of diffusions was posed in [152, p. 217]. In its original form, which requires that m has full support, the problem is very difficult and still unsolved. In the context of generalized diffusions it was independently solved by Knight [176] and Kotani and Watanabe [182]. Bertoin [35] revisited the problem and gave another proof. The proof we give follows essentially the approach from [176] and [182]. One of the key steps in the proof is the identification of the probabilistically defined Green function G .x; y/ with the analytic R .x; y/ D .x; /.y; /. This seems to be part of the folklore; since we were unable to give a precise reference, we decided to include a proof of Proposition 14.15. This proof follows [152, pp. 126–7]. The relations between m and , given in Proposition 14.16, appear in [187] and can be derived using the spectral theory of strings, see [89, p. 192]. Note that a consequence of the last formula is that r D lim!0 h./ D h.0C/. The problem of the characterization of the hitting time distributions in the case of nonsingular diffusion on an interval . r1 ; r2 / was studied by Kent in [172], see also [171] for complete proofs, and [174]. He showed that xy 2 BO if the boundary r1 is not natural. The case presented in Theorem 14.20 covers an instantaneously reflecting, non-killing left boundary. The complete characterization of hitting time distributions for generalized diffusions, Theorem 14.24, was obtained by Yamazato in [294]. A slight drawback of this result is that the condition on 2 is given in terms of the representing measure of . L .2 I // 1 . In [295] Yamazato expressed the condition on 2 in terms of the function 2 appearing in the representation (9.4).
Chapter 15
Examples of complete Bernstein functions
Below we provide a list of examples of complete Bernstein functions. We restrict ourselves to complete Bernstein functions of the form Z f ./ D
.1
e
t
.0;1/
Z / m.t/ dt D
.0;1/
.dt/: Ct
Whenever possible, we provide expressions for the representing density m.t/ and measure .dt/, respectively; for simplicity, we do not distinguish between a density and the measure given in terms of the density. We also state whether f is a Thorin– Bernstein function, i.e. whether f is of the form
f ./ D log 1 C t .0;1/ Z
.dt/:
By ‘unknown if in TBF’ we indicate that we were not able to determine whether f 2 TBF or not. The third column of the tables contains references and remarks how to derive the corresponding assertions. Some more lengthy comments can be found in Sections 15.11.1–15.11.3 below. We record here again the relations between the Lévy density m and the Stieltjes measure and the Thorin measure , cf. Remark 6.8(iii) and Remark 8.3(ii): Z m.t/ D
e
ts
s .ds/I
e
ts
.0; s/ dsI
e
ts
.ds/I
.0;1/
Z m.t/ D
.0;1/
Z t m.t/ D
.0;1/
t .dt/ D .0; t/ dt: Only a few publications contain extensive lists of (complete) Bernstein functions. We used the papers by Jacob and Schilling [159] (29 entries) and Berg [25] (11 entries) as a basis for the tables in this chapter.
15.1 Special functions used in the tables
15.1
215
Special functions used in the tables
Our standard references for this section are Abramowitz and Stegun [1], Erdélyi et al. [90, 91] and Gradshteyn and Ryzhik [111]. Trigonometric functions sec.x/ D
1 ; cos.x/
csc.x/ D
1 sin.x/
Hyperbolic functions sinh.x/ D
ex
e
x
cosh.x/ D
;
2
ex C e 2
x
;
Gamma function Z
1
.x/ D
e ttx
1
dt
0
Digamma function ‰0 .x/ D ‰.x/ D
d 0 .x/ log .x/ D dx .x/
Trigamma function ‰1 .x/ D
1 X 1 d2 log .x/ D 2 dx .x C m/2 mD0
Tetragamma function ‰2 .x/ D
1 X
d3 log .x/ D dx 3
1 .x C m/3 mD0
Incomplete Gamma functions Z
1
.˛; x/ D
t ˛ 1e
t
dt D x .˛
1/=2
e
x=2
W.˛
1/=2;˛=2 .x/
x
Z
x
t ˛ 1e
.˛; x/ D
t
dt D ˛ 1 x ˛ 1 F1 .˛; ˛ C 1;
0
Beta function Z B.x; y/ D 0
1
t x 1 .1
t /y
1
dt D
.x/ .y/ .x C y/
x/
tanh.x/ D
sinh.x/ cosh.x/
216
15 Examples of complete Bernstein functions
Incomplete Beta functions x
Z
t 1 .1
Bx .; / D
t /
1
Ix .; / D
dt;
0
Bx .; / B1 .; /
Exponential integrals 1
Z 1
E1 .x/ D 1
Em .x/ D 1
(Cauchy principal value integral if x > 0)
t
e
dt D
t
x
Z
dt
t
x
Z
t
e
Ei.x/ D
e xt dt; tm
Ei. x/ D .0; x/;
x>0
m > 2; x > 0
Sine and cosine integrals 1
Z si.x/ D x
sin t dt; t
1
Z ci.x/ D x
cos t dt; t
x>0
Error functions 2 Erf.x/ D p
x
Z
e
t2
dt;
Erfc.x/ D 1
Erf.x/
0
Bessel functions J .x/ D
1 X
. 1/n
nD0
.x=2/C2n ; nŠ . C n C 1/
Y .x/ D
J cos./ J sin./
Bessel function zeroes j;n ;
n D 1; 2; : : :
zeroes of J
Modified Bessel functions I .x/ D
1 X
.x=2/C2n ; nŠ . C n C 1/ nD0
Confluent hypergeometric functions
1 F1 .a; b; x/ D
1 X .a/k x k .b/k kŠ
kD0
K .x/ D
I 2
I .x/ sin./
.x/
.x/
15.1 Special functions used in the tables
217
Hypergeometric functions 2 F1 .a; b; c; x/ D
1 X .a/k .b/k x k .c/k kŠ
kD0
Whittaker functions of the first kind 1 M; .x/ D x C 2 e x=2 1 F1
1 C ; 2 C 1; x 2
Whittaker functions of the second kind W; .x/ D
. 2/ .2/ M; .x/ C M; . 12 / . 12 C /
.x/
Modified Whittaker functions ˆ˛;ˇ .x/ D x
1 x=2
e
where ˛ D
W; .x/;
; ˇ D
; D
.˛ C ˇ/ ˛ ˇ ; D 2 2
Parabolic cylinder functions D .x/ D 2=2C1=2 x
1=2
W=2C1=4; 1=4 .x 2 =2/
Tricomi functions .1 b/ .b 1/ 1 b x b C 1; 2 b; x/ 1 F1 .a; b; x/ C 1 F1 .a .a b C 1/ .a/ b C 1; 2 b; x/ 1 F1 .a; b; x/ 1 F1 .a D x1 b sin.b/ .a b C 1/.b/ .a/.2 b/
‰.a; b; x/ D
Lommel’s functions of two variables U .y; x/ D
1 X
. 1/n
nD0
V .y; x/ D cos
y C2n x
x2 y C C 2 2y 2
JC2n .x/ C U2
Partial sums of the exponential function en .x/ D
n X xk ; kŠ
kD0
n D 0; 1; 2; : : :
.y; x/
218
15 Examples of complete Bernstein functions
15.2
Algebraic functions
No Function f ./ 1
˛ ;
2
. C 1/˛
3
1
4
; Ca
5
p
Comment
0<˛<1
1;
0<˛<1
.1 C /˛ 1 ;
Ca
0<˛<1
a>0
;
a>0
Theorem 8.2(v)
15.2 Algebraic functions
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
˛ t .1 ˛/
S:
sin.˛/ ˛ t
T:
˛ sin.˛/ ˛ t
L:
˛ e tt .1 ˛/
S:
sin.˛/ .t 1/˛ 1.1;1/ .t/ t
T:
˛ sin.˛/ .t
L:
1 .1
˛/
sin.˛/ .t
T:
f … TBF
L:
ae
S:
ıa .dt /
T:
f … TBF e
1
1
1 ˛
1/˛
e tt
S:
L:
1 ˛
1/˛ t
1
at
.2at C 1/ p 3=2 2 t
1 t
T:
f … TBF
p
a
1.1;1/ .t/
˛
at
S:
1
1.a;1/ .t /
1.1;1/ .t/
219
220
15 Examples of complete Bernstein functions
No Function f ./ 6
; . C a/˛
7
s
; Ca
Comment Theorem 8.2(v)
a > 0; 0 < ˛ < 1
a>0
(1.18) of [39], Theorem 1 of [211], Theorem 8.2(v). See §15.11.1
0<˛<1
(1.49) of [39], Theorem 8.2(v). See §15.11.1
8
˛ ; .1 C /˛
9
˛ .1 C /˛ .1 C /˛ ˛
10
.1 C /˛ .1 C /˛ 1 0<˛<1
(1.18) of [39], Theorem 8.2(v). See §15.11.1
1
;
0<˛<1
1 C ˛ .1 C /˛ .1 C /˛ 1
1
;
Theorem 1.7.3 of [39] and Theorem 3.4* of [160], Theorem 8.2(v). See §15.11.1
15.2 Algebraic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
sin.˛/ .1
S:
sin.˛/ .t
T:
f … TBF
L:
a e 2
S:
p
at =2
a/
e
˛
t2
at ˛ 2
t
.at C 1
˛/
1.a;1/ .t /
at I0 2
1
at
˛/
I1
at 2
1.0;a/ .t /
T:
f … TBF
L:
˛ csc.˛/ 1 F1 .1 C ˛; 2;
S:
sin.˛/ ˛ 1 t .1
T:
f … TBF
L:
closed expression unknown
S:
sin.˛/ .1
T:
f … TBF
L:
˛ sin.˛/ .t
S:
˛ sin.˛/ .t
T:
f … TBF
t/
t/2˛
˛
t/
1.0;1/ .t /
t ˛ 1 .1 t/˛ 1 1.0;1/ .t/ 2.1 t /˛ t ˛ cos.˛/ C t 2˛
1/2˛
e t .t 1/˛ 2.t 1/˛ cos.˛/ C 1
1/2˛
.t 1/˛ 1 1.1;1/ .t/ 2.t 1/˛ cos.˛/ C 1
221
222
15 Examples of complete Bernstein functions
No Function f ./ 11
12
ˇ ˛
1 1
Theorem 2 of [116]
0<˛<ˇ<1
1;
˛ .1 C /˛
Comment
˛
(5.2), (5.3) of [39], Theorem 8.2(v). See §15.11.1
.1 C /ˇ 1 ˛ ˇ C1 ; .1 C /˛ ˛
0 < ˛; ˇ < 1
1 ˛ 1 ; ˛ ˛ 1 1
13
˛
14
.c ˛ ˛ / ; sin.˛/ .c /
15
2 c C 2
c > 0;
1 6 ˛ 6 2;
c > 0;
˛ ¤ 0; 1
Theorem A of [105], Corollary 6.3
1<˛<1
4.3(7) and 14.2(6) of [91], Theorem 8.2(v)
c˛ 1 c˛ C 2 cos.˛=2/ 2 sin.˛=2/ 1 < ˛ < 2; ˛ ¤ 1
˛ ; sin.˛/
4.3(9) and 14.2(7) of [91], Theorem 8.2(v)
15.2 Algebraic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
t ˛Cˇ sin..ˇ ˛// t ˇ sin.ˇ/ C t ˛ sin.˛/ t .t 2˛ 2t ˛ cos.˛/ C 1/
T:
unknown if in TBF
L:
closed expression unknown
S:
.1 t /˛ .1 t /ˇ 1 .1 t/˛Cˇ 1 ˛/ C C sin. sin.ˇ/ sin..˛ t1 ˛ t ˇ 2˛ tˇ ˛ .1 t/2˛ 2.1 t/˛ t ˛ cos. ˛/ C t 2˛
T:
f … TBF
L:
closed expression unknown
S:
1
ˇ//
t ˛ 2 .1 C t/ sin.˛/ ˛ ˛ t 2.˛ 1/ C 2t ˛ 1 cos.˛/ C 1
T:
unknown if in TBF
L:
.˛ C 2/ c ˛C1 e ct . ˛
S:
t˛ t Cc
T:
t ˛ .c C ct C ˛t / ; .t C c/2
L:
c ˛ csc.˛/ V˛C2 .2ct; 0/
S:
t˛ 1 c2 C t 2
T:
1 .˛ C 1/ c 2 t ˛ C .˛ 1/t ˛C2 ; 1 < ˛ < 2I .c 2 C t 2 /2
1; ct /
0 < ˛ < 1I
f … TBF;
1<˛<0
f … TBF;
1<˛<1
1.0;1/ .t/
223
224
15 Examples of complete Bernstein functions
No Function f ./ 16
.
˛1
C
˛2
C C
Comment ˛n
Corollary 6.3
/ 1;
0 6 ˛1 ; : : : ; ˛n 6 1
17
˛1
1 1 C ˇ C C ˛m 1 C C ˇn
0 6 ˛1 ; : : : ; ˛m 6 1;
Corollary 6.3
1
;
0 6 ˇ1 ; : : : ; ˇ n 6 1
225
15.2 Algebraic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
S:
closed expression unknown i hP i P P P 1 h Pn ˛j n k¤j ˛k cos. t j D1 sin. jnD1 ˛j / j D1 t k¤j ˛k / t i2 i2 hP hP P P P P n n k¤j ˛k sin. k¤j ˛k cos. t ˛ / C t ˛ / k k j D1 k¤j j D1 k¤j h Pn i hP i P P P n n 1 j D1 ˛j cos. k¤j ˛k sin. t ˛ / t ˛ / j k j D1 j D1 k¤j t i2 hP i2 hP P P P P n n k¤j ˛k sin. k¤j ˛k cos. C j D1 t k¤j ˛k / j D1 t k¤j ˛k /
T:
depends on the choice of the parameters ˛1 ; : : : ; ˛n
L:
closed expression unknown " P
1 t S:
"
m P
#" t
˛j Cˇk
t ˛j
cos.˛j / C
m P
j D1
T:
n P
t ˛j
cos.˛j / C
cos.ˇk / C
" P
t
cos..˛j C ˇk //
t ˛j
n P
m P
t
kD1
ˇk
cos.ˇk /
cos.ˇk / C
n P
#2 t ˇk
sin.ˇk /
kD1 ˛j
sin.˛j / C
#
n P
t
ˇk
sin.ˇk /
kD1
#2 " t ˇk
t
sin.˛j / C
j D1
j;k
cos.˛j / C
m P
j D1
#" ˛j Cˇk
#
n P kD1
#2 " t ˇk
kD1
1 t
t
˛j
j D1
j;k
j D1
"
sin..˛j C ˇk //
m P
m P
t ˛j
sin.˛j / C
j D1
depends on the choice of the parameters ˛1 ; : : : ; ˛m ; ˇ1 ; : : : ; ˇn
n P kD1
#2 t ˇk
sin.ˇk /
226
15.3
15 Examples of complete Bernstein functions
Exponential functions
No Function f ./ p 18 p .1 e 2a /;
19
p .1 C e
20
.1
21
e
p 2a
p 2 Ca
p Ca
.1 C /1=
22 e
/;
/
;
1 1C
Comment a>0
14.2(43) of [91], 2.25 and 7.78 in [228], Theorem 8.2(v)
a>0
14.60(3) of [91], 2.25 and 7.78 in[228], Theorem 8.2(v)
a>0
Appendix 1.17 of [55], Theorem 8.2(v). See §15.11.2
C1
C1
[4], p. 457, Theorem 8.2(v)
Theorem 3 of [4], Theorem 8.2(v)
15.3 Exponential functions
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
1 .2a2 p 2 t 5=2
S:
p 2 p sin2 .a t/ t
T:
f … TBF
L:
1 p 5=2 .t 2 t
S:
p 2 p cos2 .a t/ t
T:
f … TBF
L:
2
p
1 e t 5=2
t /e
a2 =t
Ct
2a2 /e
a2 =t
Ct
1=t at
2 C t .e 1=t
S:
p 2 sin2 . t a/ 1.a;1/ .t / p t a
T:
f … TBF
L:
closed expression unknown
S:
1 sin.=t / 1.1;1/ .t / .t 1/1=t
T:
f … TBF
L:
closed expression unknown
S:
1
T:
f … TBF
t
t 1
t
sin. t / 1.0;1/ .t /
1/ .1 C 2at/
227
228
15 Examples of complete Bernstein functions
No Function f ./ 23 1 C1 1C
24 . C 1/ e
25
15.4
Comment Theorem 3 of [4], Theorem 8.2(v) e
1
! 1 1C
1 C1 . C 1/ 1C
! e
Lemma 1 of [4], Theorem 8.2(v)
e 2
e 2
1
Remark before Theorem 3 of [4], Theorem 8.2(v)
Logarithmic functions
No Function f ./ 26 ; log 1 C a
Comment a>0
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
1
T:
f … TBF
L:
closed expression unknown
S:
1 t t .1
T:
f … TBF
L:
closed expression unknown
S:
1 t t
T:
f … TBF
t
t 1
1
1
sin. t / 1.0;1/ .t /
t
t/1
.1
t/
t
sin. t / 1.0;1/ .t /
t
sin. t / 1.0;1/ .t /
Lévy (L), Stieltjes (S) and Thorin (T) representation measures at
1 t
L:
e
S:
1 1.a;1/ .t / t
T:
ıa .dt /
229
230
15 Examples of complete Bernstein functions
No Function f ./ 27 log 1 C a ;
28
log
b. C a/ ; a. C b/
Comment
Theorem 8.2(v)
0
1 log 1 C ; a
29
1 a
30
a log 1 C aC a
31
. C a/ log. C a/ a>0
Theorem 8.2(v)
a>0
Theorem 1.7.3 of [39], Theorem 3.8* of [160], Theorem 8.2(v). See §15.11.1
a>0
1 ; a
a>0
log
a log a;
Theorem 3.8* of [160], Remark 8.3 (ii), (iii). See §15.11.1
Theorem 3.8 of [160]. See §15.11.1
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
1
e
at
.1 C at / t2
S:
1.0;a/ .t /
T:
f … TBF
L:
.e
S:
1 1.a;b/ .t / t
T:
f … TBF
at
e
bt
/
1 t
L:
Ei. at /
S:
1 1.a;1/ .t / t2
T:
f … TBF
L:
e at C Ei. at / at
S:
T:
L:
t
a at 2
1.a;1/ .t /
1 1.a;1/ .t / t2 1
e
at
t2
S:
t ^a t
T:
1.0;a/ .t /
231
232
15 Examples of complete Bernstein functions
No Function f ./ 32
Comment
. C b/ log. C b/
b log b
. C a/ log. C a/ C a log a; 0
33 a
log
a
;
14.2(2) in [91], 4.2(11) in [91]
a>0
2 2 a C 2a
35
a C log ; a>0 a2 C 2 2 a
14.2(4) in [91], 4.1(6) in [91]
36
2 C log2 ; aC a
14.2(26) in [91]
log
; a>0 a
14.2(3) in [91], 4.2(14) in [91]
34
a>0
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
S:
e
at
e
bt
t2 a/C ^ .b t
.t
a/
T:
1.a;b/ .t /
L:
ae at Ei. at / C t
S:
1 aCt
T:
a .a C t/2
L:
cos.at / ci.at /
S:
T: L:
t2
1
sin.at / si.at /
1 C a2
f … TBF d cos.at / ci.at / dt
sin.at / si.at /
S:
t t 2 C a2
T:
2a2 t .t 2 C a2 /2
L:
closed expression unknown
S:
t 1 1 log 2 t a a
T:
1 t 2
a
a log.t=a/ .t a/2
233
234
15 Examples of complete Bernstein functions
No Function f ./ p p 37 log. a C b/ ; p
38
Comment 14.2(27) in [91] a > 0; b > 1
p 1 2 .a C a a2 C 2/ 2 ! r a2 a C log 1C Cp 2 2
Theorem 2.2 of [177]
a2 ;
a>0
39
log 2.1
Example 3.2.3 of [54]
a/
log 1 C
p .1 C /2
4a.1
a/ ;
1
40
1 .1 C / log.1 C 1=/
(1.30) of [39], Theorem 8.2(v). See §15.11.1
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
log.at C b/ p 2 t
T:
p a t log.at C b/ C p 2.at C b/ 4 t
L:
p 1 Erf.a t=2/ 2 2t
S:
81 <2; :1
T:
t 6 a2 =2 cos 1 .a.2t /
2
81 <2;
1=2
/ C a.2t /
: 1 sin
1
pa 2t
S:
closed expression unknown
T:
1 q t
T:
1
a/
1=2
t
1=2
e t M0;0 4t
.t/ p p 1 2 a.1 a/; 1C2 a.1 a/
p 1 C 2 a.1
a/
q p 1 C 2 a.1
closed expression unknown 1 t.1
a2 =2t ; t > a2 =2
; t > a2 =2
p 1 B.1=2; 1=2/ 4 a.1 t
S:
p 1
t 6 a2 =2
L:
L:
1=2
t/
2
f … TBF
1 1.0;1/ .t/ C log . 1 C 1=t / 2
a/
t
p a.1
a/
235
236
15 Examples of complete Bernstein functions
No Function f ./
Comment
41
1 log
Theorem A of [105], Corollary 6.3
42
log C 1 log2
Theorem A of [104]
43
1 log log2
[105]
44
log2 1 log
[105]
45
1 .1 C / log 1 C
46
1
47
. C 1/ . C 2/ log. C 2/
Theorem 2.1 of [105], Corollary 6.3, Theorem 8.2(v)
1 log 1 C
Theorem 2.4 of [105]
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
t C1 t.log2 t C 2 /
T:
2 C log2 t
2 t
. 2
log t 2
C log
2 log t
t/2
closed expression unknown
L, T:
2
S:
2.1 C 1=t / log t C log2 t . 2 C log2 t/2
L, S, T:
closed expression unknown
L, S:
closed expression unknown
L:
e t .2 C t/ C t t3
S:
.1
T:
f … TBF
L:
2
t/ 1.0;1/ .t /
e t .2 C 2t C t 2 / t3
S:
t 1.0;1/ .t/
T:
f … TBF
L, S, T:
2
closed expression unknown
— T:
unknown if in TBF
237
238
15 Examples of complete Bernstein functions
No Function f ./ 48
Comment Theorem 2.3 of [105]
. C 2/ log. C 2/ . C 1/2
49
. C a/. C a C 1/ log
CaC1 Ca
Theorem 1.7.3 of [39], Theorem 3.6 of [160], Theorem 8.2(v). See §15.11.1
;
a>0
50
1
.a C 1/ .1 C .a C 1// log.1 C .a C 1// C
a ; .1 C a/ log.1 C a/
Theorem 1.7.3 of [39], Theorem 3.6* of [160], Theorem 8.2(v). See §15.11.1
a>0
51
1 log log 1 C a a>0
log log 1 C
1 ; Ca
Theorem 3.6 of [160], Theorem 1.2 of [39]. See §15.11.1
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures closed expression unknown
L, S:
L:
S:
.t
1 a/.1 C a
t/
2
1 .t/ 1 t 2 .a;1Ca/ C .log 1Ca / t a
f … TBF
L:
closed expression unknown
.1
1 1/ 2 C .log .1Ca/t
1 at /..1 C a/t
1 at
T:
f … TBF
L:
closed expression unknown
S:
8 ˆ 0; ˆ ˆ ˆ ˆ <1 1 t 2 ˆ ˆ ˆ ˆ 1 ˆ : ; t
T:
unknown if in TBF
closed expression unknown
T:
S:
— T:
.t
1 2 /
1.1=.1Ca/; 1=a/ .t/
0
1 a/.1 C a
1
log
a t C1 t a
! ; a 6t 6aC1 t >aC1
1 t / 2 C log 1Ca t t a
2 1.a;1Ca/ .t/
239
240
15 Examples of complete Bernstein functions
No Function f ./ 52
log
log log
Comment 1 C .1 C a/ ; 1 C a
Theorem 3.6* of [160], Theorem 1.2 of [39]. See §15.11.1
a>0
53
1
en log 1 lognC1 1
[103, 104, 105]
;
n2N
54
en .log / ; lognC1
n2N
55
lognC1 ; en .log /
n2N
lognC1
56 1 57
1
en log
1
[103, 104, 105]
[103, 104, 105]
[103, 104, 105] ;
n2N
p log 1 C 2 C 2 .1 C /
Theorem 3.1 of [160]. See §15.11.1
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
8 ˆ 0; ˆ 1 0 < t < 1=.1 C a/ ˆ 0 ˆ .1Ca/t 1 ˆ 1 ˆ arctan log 1 at <1 1 @ C A ; 1=.1 C a/ 6 t 6 1=a t 2 ˆ ˆ ˆ ˆ ˆ ˆ :1; t > 1=a t
T:
1 at /..1 C a/t
.1
1 2 1.1=.1Ca/;1=a/ .t/ 1/ 2 1 C log .1Ca/t 1 at
L, S, T:
closed expression unknown
L, S:
closed expression unknown
— T:
unknown if in TBF
L, S:
closed expression unknown
— T:
unknown if in TBF
L, S:
closed expression unknown
— T:
unknown if in TBF
1
t 2
t
S:
8 p 2 ˆ < arcsin. t/; t ˆ :1; t
T:
e
t=2
L:
I0
1 1 p t.1
t/
01
1.0;1/ .t /
241
242
15 Examples of complete Bernstein functions
No Function f ./ p 58 1C 1C 2 log 2
59
60
61
62
log.1 C ˛ /;
Comment Theorem 3.1* of [160]. See §15.11.1
0<˛<1
log
1 .1 C /˛
˛
log
˛ .1 C /˛
1
;
;
0<˛<1
0<˛<1
˛ c C sin.˛/ c ˛ cot.˛/ C
Example 3.2.4 of [54], Theorem 8.2(v)
(3.7) in Section 3.1.a of [160]. See §15.11.1
Theorem 3.4* of [160]. See §15.11.1
14.2(8) in [91] c c˛ log ;
c > 0; 0 < ˛ < 1
15.4 Logarithmic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
1 1 t
T:
1 1 1.1;1/ .t/ p t t 1
L:
closed expression unknown
S:
1 C t ˛ cos.˛/ 1 arccos 2˛ t .t C 2t ˛ cos.˛/ C 1/1=2
T:
1 ˛t ˛ 1 sin.˛/ 1 C t 2˛ C 2t ˛ cos.˛/
2 1 arcsin p 1.1;1/ .t/ t
L, S:
closed expression unknown
T:
˛ sin.˛/ .1
L, S:
closed expression unknown
T:
˛ sin.˛/ .t
t/2˛
1/2˛
L:
closed expression unknown
S:
1 t˛ t
T:
1 ˛t ˛C1
t ˛ 1 .1 t/˛ 1 1.0;1/ .t/ 2.1 t /˛ t ˛ cos. ˛/ C t 2˛
.t 1/˛ 1 1.1;1/ .t/ 2.t 1/˛ cos.˛/ C 1
c˛ c c.1 C ˛/ t ˛ C c 1C˛ .t c/2
243
244
15.5
15 Examples of complete Bernstein functions
Inverse trigonometric functions
No Function f ./ r 63 p a arctan ;
64
15.6
p arctan
Comment a>0
r ! ; a
a>0
Hyperbolic functions
No Function f ./ r p 65 cosh2 . 2/ p 2 sinh.2 2/
Comment 1 4
Appendix 1.5 of [55], Theorem 8.2(v). See §15.11.2
15.6 Hyperbolic functions
Lévy (L), Stieltjes (S) and Thorin (T) representation measures p p Erf at 3 1 3=2 e at t
; at D L: 2 2 2t 4t 3=2 S:
1 p 1.0;a/ .t / 2 t
T:
f … TBF
L:
2e
at
p
p p at C Erfc at 4t 3=2
S:
1 p 1.a;1/ .t / 2 t
T:
1p 1 a ıa .dt / C p 1.a;1/ .t / dt 2 4 t
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
1 X n2 2
16
nD1
S:
1 X 1 nD1
T:
2
cos2
cos2
f … TBF
n
n 2
2
e
n2 2 t=8
ın2 2 =8 .dt /
245
246
15 Examples of complete Bernstein functions
No Function f ./ r p 66 sinh2 . 2/ p 2 sinh.2 2/
67
68
69
Comment Appendix 1.6 of [55], Theorem 8.2(v). See §15.11.2
p
1 coth p 2 2
Example 2.2 of [52], Theorem 8.2(v)
p p a C tanh.b / p ; 1 C a tanh.b /
a; b > 0
p p 1/ .ı sinh 2a p p ; b 2 sinh2 a c 2 cosh2 a 1 a; b; c > 0; ı WD 2
b c
c b
Example 2, Section 2.3 of [193] and Theorem 8.2(v)
14.2(63) in [91], Theorem 8.2(v)
15.6 Hyperbolic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
1 X n2 2
16
nD1
S:
1 X 1 nD1
T:
L:
2
sin2
n
sin2
2
n 2
e
n2 2 t=8
ın2 2 =8 .dt /
f … TBF 1 X
1 e 4 n4 8 nD1
t=.4 2 n2 /
1 X
S:
1 ı1=4 2 n2 .dt / 2 2 n2 nD1
T:
f … TBF
L:
closed expression unknown
S:
2a p p t 1 C a2 C .1 a2 / cos 2b t
T:
f … TBF
L:
closed expression unknown
S:
1 p p p 2 2 t b sin a t C c 2 cos2 a t
T:
f … TBF
247
248
15 Examples of complete Bernstein functions
No Function f ./ p 70 log sinh. 2/
Comment p log. 2/
71
p log cosh. 2/
72
p log. 2/
73
p p log 1 C b tanh.a / ;
p log tanh. 2/
a; b > 0
1.431(2) of [111], 5.5(1) of [91], Corollary 6.3
1.431(4) of [111], 5.5(1) of [91], Corollary 6.3
Entry 70, Theorem 8.2(v)
14.2(71) of [91], Theorem 8.2(v)
15.6 Hyperbolic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
1 X 1 nD1
S:
1 X 1 nD1
T:
t
1 X
t
e
2 n2 t=2
1. 2 n2 =2; 1/ .t/
ı 2 n2 =2 .dt /
nD1
L:
1 X 1 nD1
S:
1 X 1 nD1
T:
t
1 X
t
e
2 .n
1. 2 .n
ı 2 .n
1 2 2 / t=2
1=2/2 =2; 1/ .t/
1=2/2 =2 .dt /
nD1
L:
1 X 1 nD1
S:
t
1 X 1 nD1
t
e
2 .n
1 2 2 / t=2
1 X 1 nD1
1. 2 .n
t
e
2 n2 t=2
1=2/2 =2; 2 n2 =2/ .t / dt
T:
f … TBF
L:
closed expression unknown
S:
p 1 p log 1 C b 2 tan2 .a t/ 2 t
T:
f … TBF
249
250
15 Examples of complete Bernstein functions
No Function f ./ p p 74 log 1 C b coth.a / ;
Comment 14.2(72b) of [91], Theorem 8.2(v)
a; b > 0
75
p p log b sinh.a / p a; C c cosh.a /
14.2(68) in [91], Theorem 8.2(v)
a > 0; b; c > 1
15.7
Inverse hyperbolic functions
No Function f ./ 76
sinh 1 ./ p p D log. 1 C C /
Comment
15.7 Inverse hyperbolic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
p 1 p log 1 C b 2 cot2 .a t/ 2 t
T:
f … TBF
L:
closed expression unknown
S:
p p 1 p log b 2 sin2 .a t/ C c 2 cos2 .a t/ 2 t
T:
f … TBF;
b¤c
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
8 p ˆ arcsin. t/ ˆ < ; 01 2t
T:
1 p 2 t.1
t/
1.0;1/ .t /
251
252
15 Examples of complete Bernstein functions
No Function f ./ 77
Comment Theorem 1.1 of [211], Corollary 6.3
cosh 1 . C 1/ D log C 1 C
p
. C 2/
78
2 1 cosh 1 . C 1/ 2
Theorem 1.3 of [211], 5.15(9) of [91]
79
s
Theorem 8.2(v)
80
log
cosh 1 . C 1/ C2
p
. C 1/2
1
See §15.11.3 below: combine entries 70 and 77, Proposition 6.2 of [211]
log cosh 1 . C 1/
81
p . C 1/2 C log cosh 1 . C 1/
log. C 1/
log
1
See §15.11.3 below: combine entries 72 and 77, Proposition 6.2 of [211]
15.7 Inverse hyperbolic functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
I0 .t/ e t
S:
8 ˆ 2 ˆ < sin t ˆ ˆ :1; t
t
r ! t ; 0
1
t >2
T:
´ 1 .2t 0;
L:
K0 .t/ e t
S:
cosh 1 .t t
T:
.t 2
L:
closed expression unknown
S:
.t 2
T:
f … TBF
L:
e t 2t
t 2/
1=2
; 02
t
2t /
2t /
1/
1=2
1=2
1.2;1/ .t/
1.2;1/ .t /
1.2;1/ .t /
cosh.t/
Z
1
I .t / d
0
S:
closed expression unknown
T:
unknown if in TBF
L:
e t 2t
2
Z cosh.t/ C
1
I .t / d
0
S:
closed expression unknown
T:
unknown if in TBF
253
254
15 Examples of complete Bernstein functions
15.8
Gamma and other special functions
No Function f ./ 82
.. C a/=.2a// ; .=.2a//
83
.˛ C 1/ ; .˛ C 1 ˛/
84
.˛ C 1 ˛/ ; .˛ C 1/
85
1
86
1
a
e .; /;
e
Comment a>0
0<˛<1
0<˛<1
2R
.; a/;
a > 0; 0 < < 1
Proposition 22 of [249]
[40] (pp. 102–103)
[40] (pp. 102–103)
(5.37) of [52]
14.2(17) in [91], 4.5(3) in [91], Theorem 8.2(v)
15.8 Gamma and other special functions
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
a3=2 e 2at p 2 .e 2at 1/3=2
S:
closed expression unknown
T:
unknown if in TBF
L:
.1
e t =˛ ˛/.1 e
t =˛ /1C˛
S:
closed expression unknown
T:
unknown if in TBF
L:
.1 ˛/2 e t =˛ ˛ .˛ C 1/ .e t =˛ 1/2
S:
closed expression unknown
T:
unknown if in TBF
L:
.2 .1
S:
e tt .1 /
T:
f … TBF
L:
.2 .1
S:
t e at .1 /
T:
f … TBF
/ .1 C t / /
/ .a C t / /
2
2
˛
255
256
15 Examples of complete Bernstein functions
No Function f ./ 87
Comment 14.2(19) and 4.5(29) in [91]
e a= .; a=/; a > 0; 0 < < 1
88
log . C a C b/ C log .a/
log . C a/
9.2.3 of [54]
log .a C b/;
a; b > 0
89
log .1 C / log 1 C 2 log 1 C
Theorem 1.3 of [24], Theorem 8.2(v)
90
1= 1 1C .1 C /
Theorem 1.3 of [24], Theorem 8.2(v)
91
p p log . / C
p
log
p
p 2
p 1 log 2
(5.5) of [52], Theorem 8.2(v)
15.8 Gamma and other special functions
257
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
2 /
.1
p .a=t /.C1/=2 KC1 .2 at /
S:
t 1 e a=t .1 /
T:
.t C a/ t 2 e .1 /
L:
S:
e
a=t
at
.1 e bt / t.1 e t /
1 X 1 nD1
t
1.n
1Ca; n 1CaCb/ .t /
T:
f 2 TBF if, and only if, b 2 N
L:
closed expression unknown
S:
´ 1 1
T:
f … TBF
L:
closed expression unknown
S:
1 j1
T:
f … TBF
L:
closed expression unknown
S:
1 p log 2 t 1
T:
f … TBF
t; 0
tt 1 t jt j.1
t /j1=t
1 e
2
p
t
sin '.t / ;
´ 1 '.t/ D 1
t; 0
258
15 Examples of complete Bernstein functions
No Function f ./ p 92 p log. / 2
Comment p ‰0 . /
p ‰1 . /
p 2
94
p 2 ‰2 . /
p
95
p
93
3=2
96
1p 1 C 2 2 p 1 ‰0 2
C ‰0
p 3 1p C ‰0 4 2 1p 1 C ‰0 4 2
(5.25a–c) of [52], Theorem 8.2(v)
(5.26a–c) of [52], Theorem 8.2(v)
(5.33a–c) of [52], Theorem 8.2(v)
14.2(73) in [91], Theorem 8.2(v)
14.2(74) in [91]
15.8 Gamma and other special functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
S:
closed expression unknown 1
e 2
p t
1
T:
f … TBF
L:
closed expression unknown
S:
p p 2 t e 2 t
.e 2
p t
1/2
T:
f … TBF
L:
closed expression unknown
S:
4 2 t .e 4 .e 2
p t
p
t
C e 2
p
t
/
1/3
T:
f … TBF
L:
closed expression unknown
S:
p csch. t/
T:
f … TBF
L:
closed expression unknown
S:
p sech t p t
T:
f … TBF
259
260
15 Examples of complete Bernstein functions
No Function f ./ 97
98
99
100
2 log log . C 1/
Comment (6) and (7) of [30], Theorem 8.2(v)
Theorem 1.2 of [31], Theorem 8.2(v)
log . C 1/ log
e En ./;
e a Ei. a/;
101 e a Ei. ab a; b > 0
(5.70) of [52], Theorem 8.2(v)
n2N
a/
a>0
Ei. a/ ;
14.2(11) in [91], 4.5(2) in [91], Theorem 8.2(v)
14.2(12) in [91], Remark 8.2 (ii), Theorem 8.2(v)
15.8 Gamma and other special functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
S:
closed expression unknown 8 ˆ <0;
t D 1; 2; : : :
log j.1 ˆ :t .log j.1
t /j C .n 1/ log t ; t /j/2 C .n 1/2 2
t 2 .n
1; n/; n D 1; 2; : : :
T:
f … TBF
L:
closed expression unknown
S:
8 ˆ t D 1; 2; : : : <1; log j.1 t /j C .n 1/ log t ˆ : ; t 2 .n 1; n/; n D 1; 2; : : : t..log t /2 C 2 /
T:
f … TBF
L:
n .1 C t/nC1
S:
1 .n
1/Š
e
T:
f … TBF
L:
1 .a C t/2
S:
e
T:
f … TBF
L:
t n 1
t
at
.b.t C a/ C 1/ e .t C a/2
1
at
S:
e
1.0;b/ .t /
T:
f … TBF
.tCa/b
261
262
15 Examples of complete Bernstein functions
No Function f ./
Comment
e a Ei. ab
102
14.2(13) in [91], Remark 8.3 (ii), Theorem 8.2(v)
a/
14.2(14) in [91], 4.5(3) in [91], Theorem 8.2(v)
103 . 1/nC1 nC1 e a Ei. a/ C
n X
. 1/n
k
.k
1/Š a
k n kC1
;
kD1
a > 0; n 2 N 104
log.a/
e a Ei. a/;
a>0
p p 105 2 cos.a / ci.a / p p 2 sin.a / si.a /;
14.2(18) in [91], 4.2(1) and 4.5(1) [91]
14.2(20) in [91], 4.5(35) in [91], Theorem 8.2(v)
a>0
106
p p p 2 sin.a / ci.a / p p C cos.a / si.a / ; a>0
14.2(21) in [91], 4.5(32) in [91], Theorem 8.2(v)
15.8 Gamma and other special functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
.b.t C a/ C 1/ e .t C a/2
S:
e
T:
f … TBF
L:
.n C 1/Š .a C t /
S:
t ne
T:
f … TBF
L:
a t.t C a/
S:
t
T:
ae
at
1
.tCa/b
1.b;1/ .t /
n 2
at
.1
e
at
/
at
2 a2 =.8t/
e
L:
3t
S:
e
T:
f … TBF
L:
a C t2
D
4
a p 2t
p a t
1=2
e
r
p a t
S:
t
T:
f … TBF
t5
a2 1 C 4 2t
ea
2 =.4t/
Erfc
a p 2 t
263
264
15 Examples of complete Bernstein functions
No Function f ./ 107 1 1C 108
p p e a Erfc. a/;
109
r
a
Comment Theorem 3.2 of [5]
a>0
p 3=2 e a Erfc. a/;
14.2(15) in [91], 4.5(3) in [91], Theorem 8.2(v)
14.2(16) in [91], 4.5(3) in [91], Theorem 8.2(v)
a>0
15.9
Bessel functions
No Function f ./
Comment
110
Formula below (2.3) of [148]
.
1/ log 2 log ./ p p C C log K . /; > 1=2
111 p 1
p ! K 1 . / ; p K . /
Entry 110 and Remark 8.3 > 1=2
15.9 Bessel functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures closed expression unknown
L, S:
L:
1 2.t C a/3=2
S:
e at p t
T:
f … TBF
L:
5 .t C a/ 2
S: T:
p
te
— T:
unknown if in TBF
5=2
at
f … TBF
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L, S:
closed expression unknown
T:
1 p 2 t
L:
S:
T:
1
2 p p p 2 t J . t/ C Y2 . t/
closed expression unknown 1 p
t
1
f … TBF
2 p p p t J2 . t/ C Y2 . t/
!
!
265
266
15 Examples of complete Bernstein functions
No Function f ./
Comment
112 .
Proof of Theorem 1 in [148]
1/ log 2 C log ./ p p log K . /; 0 < < 1=2
p 113 p K 1 . / p K . /
!
Entry 112 and Remark 8.3 (iii)
1 ;
0 < < 1=2
114 .
p log 2/ p p C log K . / log K . /; /.log
(4.2) of [149], Theorem 8.2 (ii)
0<< 115 p
p K 1 . / p K . /
p ! K 1 . / ; p K . /
Entry 114 and Remark 8.3 (iii)
0<<
p 116 p K 1 . / ; p K . /
>0
(1.3) of [146], Nicholson’s integral formula (4.13.7) of [10]
p 117 p IC1 . / ; p I . /
>0
(2.2) of [148], Theorem 8.2(v), Remark 8.3 (ii)
15.9 Bessel functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures closed expression unknown
L, S:
1 p
T:
L:
S:
T:
t
1
2 p p p t J2 . t/ C Y2 . t/
closed expression unknown 1 p
t
2 p p p 2 t J . t/ C Y2 . t/
closed expression unknown
T:
1 2t
1 p p J2 . t/ C Y2 . t/
L:
closed expression unknown
S:
2 2t
T:
f … TBF in general
1 p p J2 . t/ C Y2 . t/
closed expression unknown
S:
1 2 p p 2 t J2 . t/ C Y2 . t/
2
1 X
2 j;n e
2 t j;n
nD1
2
1 X
ıj;n 2 .dt /
nD1
T:
1
f … TBF
1 p p J2 . t/ C Y2 . t/
1 p p J2 . t/ C Y2 . t/
L, T:
S:
!
f … TBF
L, S:
L:
!
!
!
267
268
15 Examples of complete Bernstein functions
No Function f ./ p 118 1C. /=2 I . / p ; I . /
Comment Theorem 4.7 of [149], Theorem 8.2(v), Remark 8.3 (ii)
1< <61C
119 p
p I . / p p ; >0 IC1 . / C I . /
120 p
p IC1 . / p p ; >0 IC1 . / C I . /
121
1 =2
p K . / p ; KC . /
0 < < 1; 6
Theorem 9 of [215], Theorem 8.2(v)
Theorem 9 of [215], Theorem 8.2(v)
(2.1) of [147], (67) on p. 97 of [90]
p p 122 p a1 I . / C a2 I 1 . / p p ; a3 I . / C a4 I 1 . / > 0; a1 ; a2 ; a3 ; a4 > 0
Theorem 3.1 of [150]
15.9 Bessel functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
2
1 X
C3 j;n
J .j;n / J0 .j;n /
C1 j;n
J .j;n / ı 2 .dt / J0 .j;n / j;n
nD1
S:
2
1 X nD1
e
2 t j;n
T:
f … TBF
L:
closed expression unknown
S:
p J2 . t/ p p 2 t JC1 . t/ C J2 . t/
T:
f … TBF
L:
closed expression unknown
S:
p 2 JC1 . t/ p p 2 t JC1 . t/ C J2 . t/
T:
f … TBF
L:
closed expression unknown
S:
p p p p 1 JC . t/Y . t/ J . t/YC . t/ p p 2 2 t =2 . t/ JC . t/ C YC
T:
unknown if in TBF
L:
closed expression unknown
S:
p p 1 a1 a3 J2 . t/ C a2 a4 J2 1 . t/ p p p t a32 J2 . t/ C a42 J2 1 . t/
T:
unknown if in TBF
1 p
1 p
269
270
15 Examples of complete Bernstein functions
No Function f ./ p p 123 p a1 K . / C a2 K 1 . / p p ; a3 K . / C a4 K 1 . /
Comment Theorem 3.3 of [150]
> 0; a1 ; a2 ; a3 ; a4 > 0
124 2 I ap K ap ;
14.3(22) in [91], Theorem 8.2(v)
a > 0; 2 R
125 1C e a K .a/; a > 0;
126
1=2 < < 1=2
p e a K .a/; a > 0;
14.3(36) in [91]
1=2 < < 1=2
14.3(39) in [91]
15.9 Bessel functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
p p p p 2.a2 a4 C a1 a3 / a1 a3 J2 1 . t/ C Y2 1 . t/ C a2 a4 J2 . t/ C Y2 . t/ C p t p p 2 p 2 p a4 J2 1 . t/ a3 Y2 . t/ C a3 J2 . t/ C a4 Y2 1 . t/
T:
unknown if in TBF
L:
2a2 .3=2 C / t p .1 C /
S:
J2 .at /
T:
f … TBF
L:
21C a .3=2 C / t p sec./
S:
1 te sec./
T:
unknown if in TBF
L:
at
2.1C/
2 F1
3=2
1 3 C ; C ; 1 C 2; 2 2
.t C a/.t C 2a/
4a2 t2
3=2
I .at /
cos./ 21C a .t C a/3=2C ´ 3 3 2 5 2 a2 C ./ 2 F1 ; ; 1 ; 4 .t C a/2 2 4 4 .t C a/2 µ 3 3 C 2 5 C 2 a2 2 C . / 2 F1 ; ; 1 C ; Ca 2 4 4 .t C a/2
S:
cos./ p e t
T:
f … TBF
at
K .at /
271
272
15 Examples of complete Bernstein functions
15.10
Miscellaneous functions
No Function f ./ 127
I .a / 1
a
a > 0;
128
Comment
1
2 F1
1; 1
14.2(10) in [91], Lemma 2.1 in [64]
.; /;
<<1
; 2
;
a ;
a > 0; 0 < < 1
129
2 F1 1; 1 C ; 2 C ;
; a
a > 0; 0 < < 1
130
2 F1
; a
a > 0; 0 < <
/ 2a F 2 1 / 2a
; 1C ;1 ; 1; C 2a 2a
131
.2a/ .1
1; ; ; 1
/
. C .1 C
a > 0; 0 < < 1
14.2(9) in [91], Lemma 2.1 in [64]
[82]
15.10 Miscellaneous functions
Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
sin./ 1 a
S:
sin./ t
T:
unknown if in TBF
L:
closed expression unknown
S:
1 t a1
T:
f … TBF
L:
closed expression unknown
S:
a t
T:
a1
L:
./ C a 2 . /
S:
./ a 1 t ./ . /
T:
unknown if in TBF
L:
/ .at /
.2
3 2
e
at 2
W
1 2 ; 2 2
.a C t/
1.0;a/ .t /
1.a;1/ .t /
ıa .dt / C .1
a sinh.at /
1C
/ t
1
t
1
e .1
1.a;1/ .t / dt
C1 2
e
.a C t /1
/ at
S:
closed expression unknown
T:
unknown if in TBF
at 2
W1
2C ; 2 2
.at/
.at/
273
274
15 Examples of complete Bernstein functions
No Function f ./
Comment
132
[82]
2 ./ ; ;1 2 F1 1; .2 / a a ! C 2a ; 2 C ;1 F 1; C 2 1 2a 2a 2 C 2a
.2a/ .1
/
a > 0; 0 < < 1; D 133
ˆ˛;ˇ ./;
˛>
or:
ˇ>
134 .C1/=2 e a=2 W
1 <ˇ6 2 1 <˛6 2
1 ; 2 1 ; 2
C1 2 ;
1C 2
2
1 ; 2 1 2
.a/
Lemma 3.1 of [161]
[54, 217], Theorem 8.2(v)
D aC1 .C1/=2 e a . ; a/; a > 0; > 0
135 C1=2 e a=2 W a > 0;
136 e a=2 W
; .a/;
14.3(50) of [91], (9.221) of [111]
1=2 < < C 1=2
; .a/;
a > 0; jj
1=2 < < jj C 1=2
14.3(53) of [91], (9.222) of [111]
15.10 Miscellaneous functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures 1C a L: sinh.at / S:
closed expression unknown
T:
unknown if in TBF
L:
closed expression unknown t ˛Cˇ e
t
S:
ˆ ˛; ˇ .t / ˛ C ˇ C 12
T:
unknown if in TBF
L:
closed expression unknown
S:
a.C1/=2 t e ./
T:
f … TBF
L:
closed expression unknown
S:
t 1=2 e at =2 M; .at / .2 C 1/ C 21
T:
unknown if in TBF
L:
closed expression unknown
S:
t 1 e at =2 W; .at / C C 12 C 21
T:
unknown if in TBF
1 2
at
275
276
15 Examples of complete Bernstein functions
No Function f ./ 137
138 1
‰.a C 1; b C 1; / ; ‰.a; b; /
1=2
Comment a > 0; b < 1
D 1 . 1=2 / ; D . 1=2 /
>0
(1.4) of [149]
(1.3) of [149]
15.10 Miscellaneous functions Lévy (L), Stieltjes (S) and Thorin (T) representation measures L:
closed expression unknown
S:
t b e t j‰.a; b; t e i /j 2 .a C 1/ .a b C 1/
T:
unknown if in TBF
L:
closed expression unknown
S:
jD 1 p 2 . C 1/
T:
unknown if in TBF
1=2 /j 2 .i t 3=2 t
277
278
15 Examples of complete Bernstein functions
15.11
Additional comments
15.11.1
Entries 7–10, 12, 29–31, 40, 49–52, 57, 58, 60, 61
The entries 7–10, 12, 29–31, 40, 49–52, 57, 58, 60 and 61 are taken from [39] and [160]. Since these papers are written from a probabilistic point of view, we give a brief sketch how the representation measures can be derived from the information given there. Let G be a strictly positive random variable with distribution function F and assume that Z 1 dt .1 ^ t/ EŒe t G < 1: t 0 Define
1
² Z g./ WD exp
.1
e
t
/ EŒe
tG
0
³ dt : t
An application of the Frullani integral identity, cf. [39, (1.64), p. 323] yields ´ ´ Z µ µ g./ D exp E log 1 C log 1 C D exp F .dt/ : G t .0;1/ Thus, 1
Z f ./ WD
log g./ D
.1
e
t
/ EŒe
tG
0
dt D t
Z
log 1 C F .dt/ t .0;1/
is contained in TBF with the Thorin measure .dt/ D F .dt/. By Remark 8.3 (iii), f 0 ./ is in CBF with Stieltjes measure equal to the Thorin measure of f , namely F .dt/. By [39, Thm. 1.7, Point 3] we have 1 0 f ./ D E ; CG hence,
f ./ D E CG 0
Z D
.0;1/
F .dt/: Ct
We illustrate the method for the family of random variables G˛ , 0 6 ˛ 6 1. Their densities are given in formulae (3.3), (3.4), (3.5) and (3.6) of [160]: fG˛ .t/ D
˛ sin. ˛/ .1 ˛/ .1
t/2˛
t ˛ 1 .1 t/˛ 1 1Œ0;1 .t/; 2.1 t/˛ t ˛ cos. ˛/ C t 2˛
G1 is uniformly distributed on Œ0; 1 ; G0 D
1 ; 1 C exp. C /
C is a standard Cauchy random variable.
0 < ˛ < 1;
15.11 Additional comments
279
The basic formula is [160, (3.2), p. 41] saying that for 0 6 ˛ 6 1 ² Z 1 ³ dt E.e 1 .G˛ / / D exp .1 e t / EŒe t G˛ : t 0 In [160] explicit formulae for the Laplace exponent of 1 .G˛ / are provided, i.e. explicit formulae for the function g defined above with G standing for any member of the family G˛ . The distribution F .dt/ can now be computed from the density fG˛ .t/.
15.11.2
Entries 20, 65 and 66
The entries 20, 65 and 66 are from [55]. We give an explanation for 65, which comes from [55, Appendix 1.5, pp. 121–122]. Take a D 0, b D 2, x D y D 1, replace ˛ in [55] by . Then the formula for the -Green function reads p Z 1 cosh2 . 2/ D G .1; 1/ D e t p.t; 1; 1/ dt; p p 2 sinh. 2/ 0 where 1
1 p.t; 1; 1/ D 2
1 X C e 2
n2 2 t =8
2
cos
nD1
and
! n 2
Z D
e Œ0;1/
ts
.ds/; Q
1
n X1 1 cos2 ı 2 2 : Q D ı0 C 4 2 2 n =8 nD1
Thus, 1
Z G .1; 1/ D
e
t
with
e
ts
Œ0;1/
0
Hence,
Z dt
p cosh2 . 2/ p p 2 sinh. 2/
1 D 4
Z .ds/ Q D
Z Œ0;1/
Œ0;1/
1 .ds/: Q Cs
1 .ds/ Cs
1 n X 1 cos2 ı 2 2 : D 2 2 n =8 nD1
15.11.3
Entries 80 and 81
Entry 80 (and, similarly, 81) can be obtained in the following way. Entry 70 shows that p p log. 2/ f1 ./ D log sinh. 2/
280
15 Examples of complete Bernstein functions
is in CBF. From entry 78 we know that f2 ./ D
2 1 cosh 1 .1 C / 2
is also in CBF. Therefore, f1 ı f2 2 CBF. A straightforward computation gives that f1 ı f2 D f . Proposition 6.2 of [211] gives the Lévy density m.t/.
Chapter A
Appendix
In this appendix we collect a few concepts and results which are not used in a uniform way or which are particular to one branch of mathematics.
A.1
Vague and weak convergence of measures
Throughout this section E will be a locally compact separable metric space equipped with its Borel -algebra B.E/. We write M C .E/ for the set of all locally finite, inner regular Borel measures on E, i.e. the Radon measures on E. Most of the time we will use Greek letters ; ; : : : to denote elements in M C .E/; MbC .E/ are all finite measures, i.e. all 2 M C .E/ such that .E/ < 1. Full proofs for the topics in this section can be found in Bauer [18, Sections 30, 31] or Schwartz [259, vol. 3, Chapter V.13]. Definition A.1. A sequence .n /n2N in M C .E/ converges vaguely to 2 M C .E/, if Z Z lim
n!1 E
u.x/ n .dx/ D
E
u.x/ .dx/ for all u 2 Cc .E/:
(A.1)
A sequence of finite measures .n /n2N in MbC .E/ converges weakly to 2 MbC .E/, if Z Z lim
n!1 E
u.x/ n .dx/ D
E
u.x/ .dx/ for all u 2 Cb .E/:
(A.2)
We denote the closure of Cc .E/ with respect to the uniform norm kk1 by C1 .E/; these are the continuous functions vanishing at infinity. Note that .C1 .E/; k k1 / is a Banach space. It is not hard to see that we can replace (A.1) by Z Z lim u.x/ n .dx/ D u.x/ .dx/ for all u 2 C1 .E/: (A.3) n!1 E
E
Remark A.2. If E is a compact topological space, M C .E/ D MbC .E/, and vague convergence and weak convergence coincide. Weak convergence is, in general, not the weak convergence used in functional analysis. Topologically, the space of signed finite Radon measures Mb .E/ WD ¹ W ; 2 MbC .E/º can be identified with the topological dual of C1 .E/. Thus, vague convergence is actually the topological weak* convergence .Mb .E/; C1 .E//.
282
A Appendix
C Remark R A.3. Let . t / t >0 be a family of measures in M .E/ such that the function t 7! E u.x/ t .dx/ is measurable for every u 2 Cc .E/, and let be a measure on Œ0; 1/ such that Z Z ƒ.u/ WD u.x/ t .dx/ .dt/ < 1 (A.4) Œ0;1/
E
for all u 2 Cc .E/. Then ƒ defines a positive linear functional on Cc .E/ which we may identify with a measure 2 M C .E/. Formally, Z D t .dt/ Œ0;1/
and we call this a vague integral, provided that (A.4) holds for all u 2 Cc .E/. Using standard approximation techniques it is easy to show that Z .B/ D t .B/ .dt/; B 2 B.E/: Œ0;1/
We have the following relation between vague convergence and weak convergence of measures. Theorem A.4. A sequence of measures .n /n2N , n 2 MbC .E/, converges weakly to if, and only if, it converges vaguely to and if the total masses converge to the total mass of the limit lim n .E/ D .E/: n!1
A vaguely convergent sequence of measures .n /n2N , n 2 M C .E/, is necessarily vaguely bounded, i.e. for each u 2 Cc .E/ or for each compact set K E we have Z sup u dn < 1 or sup n .K/ < 1; n2N
n2N
but some kind of converse is also true. Theorem A.5. A subset F M C .E/ is vaguely relatively compact if, and only if, F is vaguely bounded. This means, in particular, that every vaguely bounded sequence of Radon measures has at least one vaguely convergent subsequence. The Banach–Alaoglu theorem for the dual pair .C1 .E/; M C .E// can thus be written as Corollary A.6 (Banach–Alaoglu). Every ball ¹ 2 MbC .E/ W .E/ 6 rº of radius r > 0 is vaguely, or weak*, compact. Weak convergence can also be characterized via the portmanteau theorem.
A.2 Hunt processes and Dirichlet forms
283
Theorem A.7. A sequence of measures .n /n2N , n 2 MbC .E/, converges weakly to a measure 2 MbC .E/ if one, hence all, of the following equivalent conditions are satisfied: (i) lim supn!1 n .F / 6 .F / for all closed sets F E; (ii) lim infn!1 n .G/ > .G/ for all open sets G E; (iii) limn!1 n .B/ D .B/ for all Borel sets B E with .@B/ D 0. If n ; are finite measures on the real line R, we can add a further equivalence in terms of their distribution functions: (iv) limn!1 n . 1; x D . 1; x for all x 2 R such that ¹xº D 0. Recall that F .x/ WD . 1; x is a distribution function and that we have a one-toone relation between finite measures on the real line and all bounded, non-decreasing and right-continuous functions F W R ! R. In the context of vague convergence and weak convergence the classical Helly’s selection theorem becomes: Corollary A.8 (Helly). If .Fn /n2N is a sequence of distribution functions which is uniformly bounded, i.e. supn2N;x2R jFn .x/j < 1, then there exists a distribution function F .x/ and a subsequence .Fnk /k2N such that lim Fnk .x/ D F .x/ at all continuity points x of F .
k!1
The corresponding sequence of finite measures, .nk /k2N converges vaguely to the finite measure induced by F . It converges weakly if, and only if, limR!1 supk ŒFnk .R/ Fnk . R/ D 0, or equivalently, if limk!1 nk .R/ D .R/. Lemma A.9. Let .n /n2N be a sequence of finite measures on Œ0; 1/. Then the vague limit D limn!1 n exists if, and only if, limn!1 L .n I x/ D g.x/ exists for all x > 0. If this is the case, g.x/ D L .I x/. The measures converge weakly if, and only if, limn!1 L .n I x/ D g.x/ for all x > 0. If this is the case, g.x/ D L .I x/. Proof. The assertion on vague convergence is a consequence of the closedness of the n!1 set CM, see the proof of Theorem 1.6. If, in addition, L .n ; 0/ D n Œ0; 1/ ! Œ0; 1/ D L .I 0/ holds, we can use Theorem A.4 to get weak convergence.
A.2
Hunt processes and Dirichlet forms
In this section we collect some basic definitions and results pertinent to Hunt processes and the theory of Dirichlet forms. Let E be a locally compact separable metric space and let E@ denote its one-point compactification. If E is already compact, then @ is
284
A Appendix
added as an isolated point. The Borel -algebras on E and E@ will be denoted by B D B.E/ and B@ WD B.E@ /, respectively. Let .; F / be a measurable space. A stochastic process with time-parameter set Œ0; 1/ and state space E is a family X D .X t / t >0 of measurable mappings X t W ! E. A filtration on .; F / is a non-decreasing family .G t / t >0 of sub- -algebras of F . T The filtration .G t / t >0 is said to be right-continuous if G t D G t C WD s>t Gs for every t > 0. The stochastic process X D .X t / t >0 is adapted to the filtration .G t / t >0 if for every t > 0, X t is G t measurable. A stopping time with respect to the filtration .G t / t >0 is a mapping T W ! Œ0; 1 such that ¹T 6 tº 2 G t for each t > 0. The -algebra GT is defined as GT D ¹F 2 F W F \ ¹T 6 tº 2 G t for all t > 0º. Let 0 WD .X W s > 0/ and for t > 0, F 0 WD .X W 0 6 s 6 t/. F1 s s t Definition A.10. Let X D .X t / t >0 be a stochastic process on .; F / with state space .E@ ; B@ /, and let .Px /x2E@ be a family of probability measures on .; F /. The family X D .X t / t>0 ; .Px /x2E@ is called a Markov process on .E; B/ if the following conditions hold true (M1) x 7! Px .X t 2 B/ is B.E/ measurable for every B 2 B.E/. (M2) There exists a filtration .G t / t >0 on .; F / such that X is adapted to .G t / t >0 and Px .X t Cs 2 B j G t / D PX t .Xs 2 B/; Px -a.s. (A.5) for every x 2 E, t; s > 0 and B 2 B.E/. (M3) P@ .X t D @/ D 1 for all t > 0. The Markov process X is called normal if, in addition, (M4) Px .X0 D x/ D 1 for all x 2 E. The condition (M2) is called the Markov property of X with respect to the filtration .G t / t >0 . Let M1 .E@ / denote the family of Rall probability measures on E@ . For 2 M1 .E@ / and ƒ 2 F we define P .ƒ/ WD E@ Px .ƒ/ .dx/. For 2 M1 .E@ / we denote 0 with respect to P and F is the P -completion by F1 the completion of F1 t T 0 of F t within F1 ; finally, set F t WD 2M1 .E@ / F t where t 2 Œ0; 1. Then .F t / t >0 is called the minimal completed admissible filtration. If X has the Markov property with respect to .F t0C / t >0 , then the filtration .F t / t >0 is right-continuous, see e.g. [102, Lemma A.2.2]. Let X be a Markov process with respect to a filtration .G t / t >0 . Then X is called a strong Markov process with respect to .G t / t >0 if the filtration .G t / t >0 is rightcontinuous and P .XT Cs 2 B j GT / D PXT .Xs 2 B/;
P -a.s.;
(A.6)
for every .G t / t >0 -stopping time T such that P .T < 1/ D 1, and for all 2 M1 .E@ /, B 2 B@ , s > 0. A Markov process X is said to be quasi left-continuous if
A.2 Hunt processes and Dirichlet forms
285
for any sequence .Tn /n>1 of .G t / t >0 -stopping times increasing to a stopping time T it holds that P lim XTn D XT ; T < 1 D P .T < 1/ for all 2 M1 .E@ /: (A.7) n!1
Definition A.11. Let X be a normal strong Markov process on .E; B.E// with respect to the filtration .G t / t >0 satisfying the following condition (M5) (i) X t .!/ D @ for every t > .!/, where .!/ D inf¹t > 0 W X t D @º is the lifetime of X; (ii) For each t > 0, there exists a map t W ! such that X t ıs D X tCs , s > 0; (iii) For each ! 2 , the sample path t 7! X t .!/ is right-continuous on Œ0; 1/ and has left limits on .0; 1/. If X is also quasi left-continuous, then X is called a Hunt process. The process X is a Hunt process if, and only if, X is a strong Markov process and quasi left-continuous with respect to the minimal completed admissible filtration .F t / t >0 , see e.g. [102, Theorem A.2.1]. Let X be a Markov process with respect to the filtration .G t / t>0 . For x 2 E, t > 0 and B 2 B.E/ define the transition function of the Markov process X by P t .x; B/ WD Px .X t 2 B/:
(A.8)
Then P t is a transition kernel on .E; B.E// in the sense that x 7! P t .x; B/ is B.E/ measurable for each B 2 B.E/, and B 7! P t .x; B/ is a sub-probability measure on B.E/ for each x 2 E. For a measurable function W E ! R we write P t .x/ WD R .y/P t .x; dy/ whenever the integral makes sense. The Markov property of X E implies that .P t / t >0 is a Markov transition function, i.e. for every B.E/ measurable non-negative function W E ! E, P t Ps D P tCs ;
t; s > 0:
(A.9)
Note that P t .x/ D Ex ..X t /1¹t<º /, where Ex denotes the expectation with respect to the probability measure Px . If we agree that every function on E is extended to E@ by letting .@/ D 0, then we can write P t .x/ D Ex ..X t //. Note that the right-continuity of t 7! X t .!/ for all ! implies that .t; !/ 7! X t .!/ is also measurable, hence .t; !/ 7! 1B .X t .!// is measurable for every B 2 B. By Fubini’s theorem it follows that t 7! P t .x; B/ D Ex 1B .X t / is also measurable. The Laplace transform of the transition function Z 1 G .x; B/ D e t P t .x; B/ dt; x 2 E; B 2 B.E/; > 0; (A.10) 0
is called the resolvent kernel of the Markov process X.
286
A Appendix
The transition function P t .x; B/ is said to be a Feller transition function if every P t maps C1 .E/ into C1 .E/ and if lim t !0 P t .x/ D .x/ for all x 2 E and for all 2 C1 .E/. If .P t / t >0 is a Feller transition function on E, then there exists a Hunt process on E having .P t / t >0 as its transition function, compare [102, Theorem A.2.2.] or [47, Theorem I.9.4.]). From now on we assume that m is a positive Radon measure on .E; B.E// with full support, i.e. supp.m/ D E. The transition function .P t / t>0 is called m-symmetric if for all non-negative measurable functions and and for all t > 0, Z Z .x/P t .x/ m.dx/ D .x/P t .x/ m.dx/: (A.11) E
E
A Hunt process X with an m-symmetric transition function P t is called an m-symmetric Hunt process. For m-symmetric transition functions we see, using Cauchy’s inequality, Z Z 2 .x/2 m.dx/; for all 2 Bb .E/ \ L2 .E; m/: P t .x/ m.dx/ 6 E
E
This implies that P t can for all t > 0 be uniquely extended to a contraction operator on L2 .E; m/ which we denote by T t . Thus, T t W L2 .E; m/ ! L2 .E; m/. It is easy to see that .T t / t >0 is a semigroup on L2 .E; m/, i.e. T t Cs D T t Ts for all t; s > 0. In the same way we can extend the resolvent kernels Gˇ , ˇ > 0, to bounded operators on L2 .E; m/ which we denote by Rˇ . The operators .Rˇ /ˇ >0 satisfy the resolvent equation R˛
Rˇ D .ˇ
˛/R˛ Rˇ ; ˛; ˇ > 0;
2 L2 .E; m/:
(A.12)
Remark A.12. The families .T t / t >0 and .Rˇ /ˇ >0 are a priori defined on the underlying Banach space, while .P t / t >0 and .Gˇ /ˇ >0 are given by the process and have a pointwise meaning. It is possible to show, cf. [102, Theorem 4.2.3], that we have T t u D P t u and Rˇ u D Gˇ u m-almost everywhere on E. Assume that X is an m-symmetric Hunt process with transition function .P t / t >0 . Then it holds that lim P t .x/ D lim Ex .X t / D .x/ for all x 2 E and all 2 Cc .E/:
t !0
t !0
This implies, see e.g. [102, Lemma 1.4.3], that the semigroup .T t / t >0 is strongly continuous: L2 - lim t !0 T t D for every 2 L2 .E; m/. Similarly, the resolvent .R />0 is strongly continuous in the sense that L2 - lim!1 R D for every 2 L2 .E; m/. The (infinitesimal) generator A of a strongly continuous semigroup .T t / t >0 on 2 L .E; m/ is defined by ´ A WD lim t !0 T t t ® ¯ (A.13) D.A/ WD 2 L2 .E; m/ W A exists as a strong limit :
A.2 Hunt processes and Dirichlet forms
287
Let .G />0 be a strongly continuous resolvent on L2 .E; m/. It follows from the resolvent equation (A.12) and the strong continuity that G is invertible. The generator A of .G />0 on L2 .E; m/ is defined by ´ A WD G 1 (A.14) D.A/ WD G .L2 .E; m//: Note that the resolvent equation shows that A and D.A/ are independent of > 0. Lemma A.13. The generator of a strongly continuous resolvent is a negative semidefinite self-adjoint operator. Moreover, the generator of a strongly continuous semigroup coincides with the generator of its resolvent. Since the operator A is positive semi-definite and self-adjoint we can use the spectral calculus to define its non-negative square root . A/1=2 with the domain D.. A/1=2 /. Definition A.14. Let X be an m-symmetric Hunt process on E, .T t / t >0 the corresponding strongly continuous semigroup on L2 .E; m/, and A the generator of the semigroup. The Dirichlet form of X is the symmetric bilinear form E on L2 .E; m/ defined by ´ E.; / D h. A/1=2 ; . A/1=2 iL2 (A.15) D.E/ D D.. A/1=2 /: Here h; iL2 denotes the inner product in L2 .E; m/. The form E is a closed symmetric form on L2 .E; m/. For ˇ > 0 let Eˇ .; / WD E.; / C ˇh; iL2 ;
;
2 D.E/:
Then .D.E/; Eˇ / is a Hilbert space. Since the semigroup .T t / t >0 is Markovian, the form E is also Markovian, cf. [102, Theorem 1.4.1], which means that all normal contractions operate on E, see [102, p. 5]. The Dirichlet form E of X is called regular if there exists a subset C of D.E/ \ Cc .E/ such that C is dense in D.E/ with respect to E1 and dense in Cc .E/ with respect to the uniform norm. Clearly, R .L2 .E; m// D G .L2 .E; m// D D.A/ D.E/. Therefore the connection between the resolvent .R />0 and the Dirichlet form E can be expressed by E .R ; / D h; iL2 ; 2 L2 .E; m/; 2 D.E/: (A.16) For an open set B E let ® ¯ Cap.B/ WD inf E1 .; / W > 1 m-a.e. on B ;
(A.17)
and for an arbitrary A E, ® ¯ Cap.A/ WD inf Cap.B/ W B open, B A :
(A.18)
288
A Appendix
Then Cap.A/ is called the 1-capacity or simply the capacity of the set A. Let A E. A statement depending on points in A is said to hold quasi everywhere (q.e. for short) if there exists a set N A of zero capacity such that the statement holds for all points in A n N . For any open subset D of E, let D D inf¹t > 0 W X t … Dº be the first exit time of X from D. The process X D obtained by killing the process X upon exiting from D is defined by ´ X t ; t < D ; D X t WD @; t > D : Then X D is again an m-symmetric Hunt process on D. The Dirichlet form associated with X D is .ED ; D.ED // where ED D E and D.ED / D ¹u 2 F W u D 0 E-q.e. on E n Dº;
(A.19)
cf. [102, pp. 153–154]. Let .P tD / t >0 and .GD />0 denote the transition semigroup and resolvent of X D . For > 0 let HD .x/ WD Ex e D .XD / : Then for every 2 L2 .E; m/ such that D 0 q.e. on E n D, it holds that G .x/ D GD .x/ C HD G .x/
for x 2 D;
(A.20)
and E .GD ; HD G / D 0. This is the E -orthogonal decomposition of G into GD 2 D.ED / and its complement, cf. [102, Sections 4.3 and 4.4]. Definition A.15. A measure on .E; B.E// is called smooth if it charges no set of zero capacity and if there exists an increasing sequence .Fn /n>1 of closed sets such that .Fn / < 1 for all n > 1 and lim Cap.K n Fn / D 0
n!1
for every compact set K. Every Radon measure on .E; B.E// that charges no set of zero capacity is smooth, see [102, p. 81]. For a Borel set B E, let TB D inf¹t > 0 W X t 2 Bº be the hitting time of X to B. A set N E is called exceptional for X if there exists a Borel set NQ N such that Pm .TNQ < 1/ D 0. Definition A.16. Let C D .C t / t >0 be a stochastic process with values in Œ0; 1. Then C is called a positive continuous additive functional (PCAF) of X if
A.2 Hunt processes and Dirichlet forms
289
(a) C is adapted to the minimal completed admissible filtration .F t / t >0 and if there exists a set ƒ 2 F1 and an exceptional set N E such that (b) Px .ƒ/ D 1 for all x 2 E n N , (c) t ƒ ƒ for all t > 0, (d) t 7! C t .!/ is continuous on Œ0; .!// for all ! 2 ƒ, (e) for all ! 2 ƒ we have 8 ˆ t D 0; .!/; (f) C t Cs .!/ D C t .!/ C Cs . t !/;
s; t > 0:
Two positive continuous additive functionals C .1/ and C .2/ are equivalent if for .1/ .2/ each t > 0 and for quasi every x 2 E we have Px C t D C t D 1. Let C D .C t / t >0 be a positive continuous additive functional of X. For a Borel function W E ! Œ0; 1/ and > 0 define Z t UC .x/ WD Ex e .X t / dC t : Œ0;1/
The PCAF C and the smooth measure are said to be in Revuz correspondence if for every > 0 and all non-negative Borel functions and it holds that Z h; UC iL2 D .G / d: (A.21) In this case, the measure is called the Revuz measure of the PCAF C . The condition (A.21) is one of several equivalent conditions describing the Revuz correspondence; for the others we refer to [102, Theorem 5.1.3]. Theorem A.17. The family of all equivalence classes of positive continuous additive functionals of X and the family of all smooth measures are in one-to-one correspondence under the Revuz correspondence.
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Index
A additive functional, 288 analytic function of bounded type, 58 canonical factorization, 58
B Balakrishnan’s formula, 145 Bernstein function, 15, 132 characterization, 19, 142 complete, see complete Bernstein function cone structure, 20 convergence of, 21 definition, 15 extended, 38, 60, 89 extremal representation, 24 is negative definite, 28, 31 Lévy measure, 15 Lévy triplet, 15 Lévy–Khintchine representation, 15, 37, 43, 46, 49, 115, 135, 186 relation with CM, 19, 35, 39 special, see special Bernstein function stability, 20 Bernstein’s theorem, 3, 17, 29, 50 Bochner’s theorem, 32 Bochner–Schoenberg theorem, 142 Bondesson class, 80 and first passage time, 206 as vague closure, 83 definition, 80 stability, 80 BO ID, 80 BO 6 SD, 91
C capacity, 162, 288
Choquet representation for BF, 24 for CBF, 65 for CM, 7 for S, 13 for TBF, 77 for positive definite fns, 29–31 complete Bernstein function, 49 and inverse local time, 187 characterization, 49–50, 62, 63, 66, 67, 112 cone structure, 64 conjugate pair, 62 convergence of, 65 definition, 49 exponential representation, 58, 67, 68, 82, 87 extremal representation, 65 is Nevanlinna–Pick function, 49 is operator monotone, 121 is Pick function, 49 Lévy density vs. Stieltjes measure, 57 log-convexity of CBF, 67, 68, 70 multiplicative representation, 60 Nevanlinna representation, 56, 70 potential density, 95 relation between Lévy density and Stieltjes measure, 165 relation with S, 63, 66–67 stability, 63, 64, 71, 81 Stieltjes measure, 55 Stieltjes representation, 55, 62, 63, 65, 69, 80, 112, 116 CBF SBF, 92 completely monotone function, 2 cone structure, 5 convergence of, 7
310
Index
definition, 2 extremal representation, 7 infinitely divisible, 37 is positive definite, 28, 31 iterated differences, 30 logarithmically, see log-completely monotone representation, 3 self-decomposable, 41 stability, 5, 20, 21, 43, 283 stable, 40 convolution of exp. distributions, 87 and first passage time, 206, 210 CE GGC, 88 convolution semigroup, 34, 132, 135 characterization, 35 definition, 34 potential measure of, 44 subordinate, 46
D Dirichlet form, 161, 287 dissipative operator, 111, 131 spectrum, 111 distribution S-self-decomposable, 86 infinitely divisible, 37, 39 Laplace exponent of, 90 overview, 89 relations among, 90 self-decomposable, 41 stable, 40
E excessive function, 178
F Feller transition function, 286 first passage time and BO, 206 and CE, 206, 210 and GGC, 206
and ME, 210 generalized diffusion, 202 fractional power, 91 Balakrishnan’s formula, 145 in BF, viii, 15, 24 in CBF, ix, 65 in CM, viii, 41 in S, ix, 13 in TBF, ix of operators, 145 functional calculus, 150
G generalized diffusion, 186 first passage time, 202 inverse local time, 187 local time, 186 generalized Gamma convolution, 84 and first passage time, 206 as vague closure, 85 definition, 84 stability, 84 GGC BO, 84 GGC SD, 84 GGC 6 ME, 91
H harmonic function, 179 Heinz–Kato inequality, 122 Hellinger–Stone formula, 113 Helly’s selection theorem, 283 Hirsch function, 105 characterization, 105 cone structure, 105 definition, 105 relation with P, 107 relation with SBF, 107 relation with S, 107 stability, 105 Hunt process, 161, 185, 285
I inconsistency
Index
unavoidable, 1–313 infinitely divisible, see distribution, random variable inverse local time and CBF, 187 generalized diffusion, 187
K killed Brownian motion, 177 killed process, 162 subordinate, 164 Kre˘ın correspondence, 201 examples, 201–202 Kre˘ın representation problem, 201 Kre˘ın–Milman representation, see Choquet representation
L Lévy process, 118, 142, 170 Lévy triplet, 15 Laplace exponent, 35 of distribution, 89 relations among, 90 Laplace transform, 1 Lévy–Khintchine formula, 32 local time generalized diffusion, 186 log-CM, 89 log-S, 89 log-completely monotone function characterization, 38 definition, 38 relation with P, 45 log-convex function, 97 log-convex sequence, 97, 105
311
resolvent kernel, 285 semigroup, 286 strong, 284 transition function, 285 Markov property, 284 strong, 284 matrix monotone function, 119 measure Lévy, 15, 214 Nevanlinna–Pick, 57 Pick, 57 Stieltjes, 55, 214 Thorin, 75, 214 mixture of exponential distributions and first passage time, 210 characterization, 81 definition, 81 stability, 83 ME BO, 83 ME 6 GGC, 91 ME 6 SD, 91 monotone matrix function, 119
N negative definite function, 26, 142 in the sense of Schoenberg, 32, 118, 142 Nevanlinna factorization, 58 Nevanlinna–Pick function, 56 Nevanlinna–Pick measure, 57
O operator monotone function definition, 119 is CBF, 126
M
P
Markov process, 284 definition, 284 generator, 286 normal, 284 quasi left-continuous, 284
Phillips’ theorem, 135 Pick function, 56 portmanteau theorem, 282 positive definite function, 25 conditionally, 26
312
Index
in the sense of Bochner, 32 potential, 45, 174 relation with H, 107 potential measure, 44 -potential measure, 45 potential operator, 174 -potential operator, 187
Q quasi everywhere, 162, 288
R random variable infinitely divisible, 37, 39 stable, 40 representing measure for BF, 15 for CBF, 55 for CM, 4 for S, 12 for TBF, 75 resolvent equation, 110, 131, 286 Revuz measure, 289
S S-self decomposable distribution characerization, 86 definition, 86 is GGC \ ME, 86 Schoenberg’s theorem, 26 Schoenberg–Bochner theorem, 142 self-adjoint operator dissipative, 111, 131 order, 119 resolvent, 110, 131 resolvent equation, 110 resolvent estimate, 131 spectral theorem, 114 spectrum, 110, 131 self-decomposable distribution, 41 Lévy measure of, 42 SD 6 BO, 90
SD 6 ME, 90 semigroup, see also convolution semigroup, see also subordinate semigroup algebraic, 25 C0 -semigroup, 130 contraction semigroup, 130, 132 generator, 130, 286 intrinsically ultracontractive, 174, 178 strongly continuous, 130, 286 ultracontractive, 165 smooth measure, 288 special Bernstein function, 92, 97 cone structure, 103 conjugate Lévy triplet, 95 conjugate pair, 92 counterexample, 102–103 definition, 92 potential density, 94 relation with H, 107 stability, 103 SBF 6 CBF, 102–103 special functions, 215–217 special subordinator, 92, 97, 174 characterization, 93 factorization of potential density, 96, 175, 176 potential density, 94 spectral theorem, 114, 120 Stieltjes function, 11 and string, 190 cone structure, 12 definition, 11 extremal representation, 13 log-convexity of S, 67 primitive, 70–71 relation with CBF, 63, 66–67 relation with H, 107 stability, 12, 64, 83 Stieltjes inversion formula, 55
Index
Stieltjes transform, see Stieltjes function string, 185 and Stieltjes function, 190 characteristic function, 191 definition, 185 dual, 201 length, 185 subordinate generator, 133 CBF-subordinator, 149 domain, 138, 148, 156–158 functional calculus, 150–151 limits, 158 moment inequality, 139 operator core, 134 Phillips’ formula, 135 spectrum, 141 subordinate process, 46, 141, 163 killed, 164 subordinate semigroup, 46, 133 definition, 133 in Hilbert space, 133 of measures, 46 subordinator, 35, 141 killed, 36 transition probabilities, 35 symmetric ˛-stable process, 170
T table of Kre˘ın correspondences, 201–202 of distributions, 89–90 of Laplace exponents, 89–90 Thorin–Bernstein function, 73 characterization, 73, 76, 86 cone structure, 77 definition, 73 extremal representation, 77, 85 is in CBF, 73 relation with S, 77 Thorin measure, 75
313
Thorin representation, 75, 77, 84 transition function, 35, 285
V vague convergence, 281 vague integral, 282
W weak convergence, 281
Overview of the classes of distributions, Laplace transforms and exponents measure
Laplace transform
Laplace exponent
references
ID
log-CM
extended BF
5.6, 5.8, 5.9
ID, Œ0; 1/ 6 1
log-CM, f .0C/ 6 1
BF
5.7
SD
—
BF, .dt/ D m.t/ dt,
5.15
t m.t/ non-increasing BO
—
CBF
ME
S, f .0C/ 6 1
CBF, .dt/ D
9.1, 9.2 .t/ t
dt ,
9.4, 9.5
0 6 .t/ 6 1 GGC CE Exp
BF
log-S, f .0C/ 6 1 Q e c n 1 C bn 1 1 C b
TBF 1
TBF; D
8.7, 9.9, 9.10 P
TBF; D ıb
n ıbn
(9.8), 9.15 9.15
Integral representations for various classes of Bernstein functions Z f ./ D a C b C .1 e t / .dt/
(3.2)
.0;1/
Z CBF
f ./ D a C b C
.1
e
t
/ m.t/ dt;
m 2 CM
(6.1)
.0;1/
Z D a C b C .0;1/
Z D ˛ C ˇ C .0;1/ 1
Z D exp C
0
.dt/ Ct
(6.5)
t 1 .dt/ Ct
(6.7)
t 1 C t2
Z TBF
f ./ D a C b C
.1
e
1 Ct t
.t/ dt ;
/ m.t/ dt;
.t/ 2 Œ0; 1
(6.10)
t m.t/ 2 CM
(8.1)
.0;1/
log 1 C .dt/ t .0;1/ Z 1 w.t/ dt; D a C b C C t t 0 Z
D a C b C
(8.2) w non-decreasing
(8.3)
(a; b; ˛; ˇ > 0; 2 R — all measures and densities are such that the integrals converge)
Relations between various classes of distributions. . .
BO ME Exp
GGC CE
ID
SD
. . . and their Laplace exponents
CBF t dσ dt ∈ [0, 1] τ =δb P τ = δbn n
BF
t dµ dt
non-increasing
TBF